{"problem": "QPC001_A1", "user": "A00026B90612D", "submission_order": 1, "result": "WA", "execution_time": "1926 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A00026B90612D", "submission_order": 2, "result": "AC", "execution_time": "935 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A00F10B73E880", "submission_order": 1, "result": "AC", "execution_time": "2025 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A02100124E940", "submission_order": 1, "result": "AC", "execution_time": "1015 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A02466477DF53", "submission_order": 1, "result": "AC", "execution_time": "915 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A04461D07E78B", "submission_order": 1, "result": "RE", "execution_time": "863 ms", "memory": "81 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.draw(\"mpl\")\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A04461D07E78B", "submission_order": 2, "result": "AC", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A05248569FD23", "submission_order": 1, "result": "AC", "execution_time": "1407 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A060207CFB8CD", "submission_order": 1, "result": "AC", "execution_time": "1989 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A065D31B2B65A", "submission_order": 1, "result": "AC", "execution_time": "906 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0793B7C0B797", "submission_order": 1, "result": "AC", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0850D310FE90", "submission_order": 1, "result": "RE", "execution_time": "1622 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    # 111量子ビットの量子回路を作成\n    qc = QuantumCircuit(111)\n    # 全ての量子ビットにアダマールゲートを適用\n    for i in range(111):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0850D310FE90", "submission_order": 2, "result": "AC", "execution_time": "1751 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # ゼロ状態 |0> に対して H ゲートを適用する\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A089E11595D19", "submission_order": 1, "result": "AC", "execution_time": "948 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A095730A588ED", "submission_order": 1, "result": "AC", "execution_time": "1060 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0ABD1FCE6E07", "submission_order": 1, "result": "AC", "execution_time": "951 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0ADEA1F46CD4", "submission_order": 1, "result": "AC", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0AEDB3AA18CD", "submission_order": 1, "result": "AC", "execution_time": "1122 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0B2E74F72D7D", "submission_order": 1, "result": "AC", "execution_time": "1904 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0CC71E1FA93D", "submission_order": 1, "result": "AC", "execution_time": "1068 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0);\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0DDE0FC0B6FC", "submission_order": 1, "result": "AC", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0E91A208A389", "submission_order": 1, "result": "AC", "execution_time": "929 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)    \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0F5D50391E07", "submission_order": 1, "result": "AC", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A0F7FAA6B5086", "submission_order": 1, "result": "AC", "execution_time": "1088 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A109097F60285", "submission_order": 1, "result": "WA", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n \n    # Apply X gate to the 1st qubit (index 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A109097F60285", "submission_order": 2, "result": "AC", "execution_time": "1098 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n \n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A10CCFF929185", "submission_order": 1, "result": "AC", "execution_time": "1451 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A111FE78EE306", "submission_order": 1, "result": "AC", "execution_time": "1646 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A116B7EEB8677", "submission_order": 1, "result": "WA", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A116B7EEB8677", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.initialize([1/np.sqrt(2), 1/np.sqrt(2)],0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A116B7EEB8677", "submission_order": 3, "result": "AC", "execution_time": "870 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    # Apply Hadamard gate to the 1st qubit (index 0)\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A11BA1FA55014", "submission_order": 1, "result": "AC", "execution_time": "1584 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1260D5108A0C", "submission_order": 1, "result": "AC", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A129D93326EC1", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A12CC6DB3EE06", "submission_order": 1, "result": "AC", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A13D95CBD5A84", "submission_order": 1, "result": "AC", "execution_time": "1343 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A14C864D0E749", "submission_order": 1, "result": "AC", "execution_time": "1075 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A14CE11B071E8", "submission_order": 1, "result": "AC", "execution_time": "1521 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1551C04365C9", "submission_order": 1, "result": "RE", "execution_time": "744 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.H(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1551C04365C9", "submission_order": 2, "result": "RE", "execution_time": "743 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.H(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1551C04365C9", "submission_order": 3, "result": "AC", "execution_time": "924 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(\n    HGate(),  # New HGate instruction\n    [0]       # Apply to qubit 0\n)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A15934C70FACD", "submission_order": 1, "result": "AC", "execution_time": "1065 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A169357D5C30D", "submission_order": 1, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A16C346E97076", "submission_order": 1, "result": "AC", "execution_time": "775 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A179EF0C7F9EF", "submission_order": 1, "result": "AC", "execution_time": "928 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A181F5CEB9CA7", "submission_order": 1, "result": "AC", "execution_time": "1571 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A18C46DB9B321", "submission_order": 1, "result": "AC", "execution_time": "1473 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A18DBD82073DE", "submission_order": 1, "result": "AC", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A193FE1B5B0D5", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A19FF5D432C37", "submission_order": 1, "result": "AC", "execution_time": "1496 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1AADFBD42DDA", "submission_order": 1, "result": "AC", "execution_time": "793 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1B2AC8BC8787", "submission_order": 1, "result": "AC", "execution_time": "1884 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1CD8EC8F3E5A", "submission_order": 1, "result": "AC", "execution_time": "966 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1E45DEE36549", "submission_order": 1, "result": "AC", "execution_time": "1490 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1E9FF62A5743", "submission_order": 1, "result": "AC", "execution_time": "1067 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1EDC34CE10B6", "submission_order": 1, "result": "RE", "execution_time": "1209 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A1EDC34CE10B6", "submission_order": 2, "result": "AC", "execution_time": "1419 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A200205C341CB", "submission_order": 1, "result": "AC", "execution_time": "1859 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    #qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A2016EA1CBA49", "submission_order": 1, "result": "AC", "execution_time": "1173 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A20ED1D1B406B", "submission_order": 1, "result": "AC", "execution_time": "987 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A21B439FB228C", "submission_order": 1, "result": "AC", "execution_time": "1132 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A234813B53250", "submission_order": 1, "result": "WA", "execution_time": "937 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A234813B53250", "submission_order": 2, "result": "AC", "execution_time": "1046 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A239C9C5A6CA5", "submission_order": 1, "result": "AC", "execution_time": "1795 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A23AE53AAA812", "submission_order": 1, "result": "AC", "execution_time": "1292 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A23E365539319", "submission_order": 1, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A244FE597B5E9", "submission_order": 1, "result": "RE", "execution_time": "1788 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.HGate(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A244FE597B5E9", "submission_order": 2, "result": "AC", "execution_time": "1835 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.append(HGate(), [0])\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A26FADFE6F982", "submission_order": 1, "result": "AC", "execution_time": "1427 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A27678954B613", "submission_order": 1, "result": "AC", "execution_time": "1840 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A278332FD7932", "submission_order": 1, "result": "AC", "execution_time": "1121 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A27D863214218", "submission_order": 1, "result": "RE", "execution_time": "826 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A27D863214218", "submission_order": 2, "result": "AC", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A282A96A0B22F", "submission_order": 1, "result": "AC", "execution_time": "1836 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A29B32000FF08", "submission_order": 1, "result": "AC", "execution_time": "1896 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A2A04530C3958", "submission_order": 1, "result": "WA", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A2A04530C3958", "submission_order": 2, "result": "AC", "execution_time": "1453 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A2A44BCAE3417", "submission_order": 1, "result": "AC", "execution_time": "1456 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A2BFC1F0EBBCA", "submission_order": 1, "result": "AC", "execution_time": "870 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A2F093DB9EF21", "submission_order": 1, "result": "AC", "execution_time": "1839 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A31099932C81F", "submission_order": 1, "result": "RE", "execution_time": "1640 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A31099932C81F", "submission_order": 2, "result": "RE", "execution_time": "1747 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(HGate(),[0],)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A31099932C81F", "submission_order": 3, "result": "AC", "execution_time": "1786 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(HGate(),[0],)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3175CF5CD5CF", "submission_order": 1, "result": "AC", "execution_time": "1159 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A318F4ED790E6", "submission_order": 1, "result": "AC", "execution_time": "847 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A32A93D934476", "submission_order": 1, "result": "AC", "execution_time": "915 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A335D19B0CF14", "submission_order": 1, "result": "AC", "execution_time": "1959 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A33B0EB1DBBC5", "submission_order": 1, "result": "AC", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A33CC44021CB1", "submission_order": 1, "result": "AC", "execution_time": "1872 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A340D4C1DB520", "submission_order": 1, "result": "AC", "execution_time": "1948 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A341F90CA931C", "submission_order": 1, "result": "AC", "execution_time": "1351 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A359E9B39045F", "submission_order": 1, "result": "AC", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0);\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A35F0C967A2CF", "submission_order": 1, "result": "AC", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3629F59C8D64", "submission_order": 1, "result": "AC", "execution_time": "1279 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A366479080494", "submission_order": 1, "result": "AC", "execution_time": "1337 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A36A5958636A3", "submission_order": 1, "result": "AC", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A36F2504A9980", "submission_order": 1, "result": "AC", "execution_time": "2048 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A38614A279415", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A38614A279415", "submission_order": 2, "result": "AC", "execution_time": "1597 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A391D5EA61A67", "submission_order": 1, "result": "AC", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A39E226CD1DF9", "submission_order": 1, "result": "AC", "execution_time": "1605 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3A2724E9AF63", "submission_order": 1, "result": "AC", "execution_time": "1746 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3BD2BC684737", "submission_order": 1, "result": "AC", "execution_time": "921 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3D66EC281343", "submission_order": 1, "result": "RE", "execution_time": "1056 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h();\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3D66EC281343", "submission_order": 2, "result": "AC", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0);\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3DD5F1843EF2", "submission_order": 1, "result": "WA", "execution_time": "1614 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3DDE71077C15", "submission_order": 1, "result": "AC", "execution_time": "903 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3E599CF88AC9", "submission_order": 1, "result": "AC", "execution_time": "1689 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A1", "user": "A3EA366BA2779", "submission_order": 1, "result": "AC", "execution_time": "1496 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3EC0C6BA6D56", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A3F5C7BAF307E", "submission_order": 1, "result": "AC", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A40547B562B9B", "submission_order": 1, "result": "RE", "execution_time": "875 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A40547B562B9B", "submission_order": 2, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A407EB93113B2", "submission_order": 1, "result": "AC", "execution_time": "1427 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A40CAD0AAF664", "submission_order": 1, "result": "AC", "execution_time": "1331 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A41C52C6A0860", "submission_order": 1, "result": "AC", "execution_time": "1617 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A42FB21582E95", "submission_order": 1, "result": "AC", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A432603E1CB2C", "submission_order": 1, "result": "AC", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A43EC0D6C9CD2", "submission_order": 1, "result": "AC", "execution_time": "1556 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# from qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    \n    print(qc)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A1", "user": "A4489941678E5", "submission_order": 1, "result": "AC", "execution_time": "889 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A46E729F3AC88", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import *\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A46E729F3AC88", "submission_order": 2, "result": "TLE", "execution_time": "2000 ms", "memory": "89 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A46E729F3AC88", "submission_order": 3, "result": "AC", "execution_time": "1297 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4828E3E1A8E7", "submission_order": 1, "result": "AC", "execution_time": "1917 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A487DC04DDC51", "submission_order": 1, "result": "AC", "execution_time": "1555 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4890D4E8660E", "submission_order": 1, "result": "AC", "execution_time": "904 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    # Hゲートを適用\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A49760170B913", "submission_order": 1, "result": "AC", "execution_time": "1466 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4CF6E1BA1D86", "submission_order": 1, "result": "RE", "execution_time": "1467 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4CF6E1BA1D86", "submission_order": 2, "result": "AC", "execution_time": "1485 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4E081D9F46AC", "submission_order": 1, "result": "RE", "execution_time": "805 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4E081D9F46AC", "submission_order": 2, "result": "RE", "execution_time": "837 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4E532C54231E", "submission_order": 1, "result": "AC", "execution_time": "1555 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4E5F53614BC1", "submission_order": 1, "result": "AC", "execution_time": "1035 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4EDBBD0B89F5", "submission_order": 1, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Add an Hadamard gate\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A4FDC31122CAC", "submission_order": 1, "result": "AC", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A50DE444B3BAD", "submission_order": 1, "result": "RE", "execution_time": "1486 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc[0].h()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A50DE444B3BAD", "submission_order": 2, "result": "AC", "execution_time": "1491 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A51D619E73BC2", "submission_order": 1, "result": "RE", "execution_time": "1444 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(i)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A51D619E73BC2", "submission_order": 2, "result": "RE", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.qubits\n    qc.g(i)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A51D619E73BC2", "submission_order": 3, "result": "AC", "execution_time": "1354 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A51F51A0AA921", "submission_order": 1, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A51F79482F743", "submission_order": 1, "result": "AC", "execution_time": "1156 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5220199A65AE", "submission_order": 1, "result": "AC", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A52C508E7FD0E", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A52D627B9B99D", "submission_order": 1, "result": "AC", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A534F92DB59D5", "submission_order": 1, "result": "AC", "execution_time": "902 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A537836004158", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.(h)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A537836004158", "submission_order": 2, "result": "AC", "execution_time": "1367 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A53871B4C7302", "submission_order": 1, "result": "AC", "execution_time": "1400 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A53AD242AF18D", "submission_order": 1, "result": "AC", "execution_time": "1453 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A549E21B98D05", "submission_order": 1, "result": "RE", "execution_time": "1358 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(\n    HGate(),  \n    [0]       \n)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A549E21B98D05", "submission_order": 2, "result": "RE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(\n    HGate(),  \n    [0]       \n    )\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A549E21B98D05", "submission_order": 3, "result": "RE", "execution_time": "1328 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(HGate(),[0])\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A549E21B98D05", "submission_order": 4, "result": "AC", "execution_time": "1455 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A54A0A4A5A6CD", "submission_order": 1, "result": "AC", "execution_time": "1435 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A55378686D93A", "submission_order": 1, "result": "WA", "execution_time": "888 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A55C3B40710FC", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit_aer import Aer \nimport matplotlib.pyplot as plt \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return  qc\n'''"}
{"problem": "QPC001_A1", "user": "A55C3B40710FC", "submission_order": 2, "result": "AC", "execution_time": "1455 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return  qc\n'''"}
{"problem": "QPC001_A1", "user": "A55EC7C7F82A2", "submission_order": 1, "result": "AC", "execution_time": "1496 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5623BDD0BEA7", "submission_order": 1, "result": "RE", "execution_time": "763 ms", "memory": "79 MiB", "code": "'''python\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5623BDD0BEA7", "submission_order": 2, "result": "WA", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5623BDD0BEA7", "submission_order": 3, "result": "RE", "execution_time": "1328 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5623BDD0BEA7", "submission_order": 4, "result": "RE", "execution_time": "789 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5623BDD0BEA7", "submission_order": 5, "result": "WA", "execution_time": "1099 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5623BDD0BEA7", "submission_order": 6, "result": "AC", "execution_time": "1564 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5657735FB809", "submission_order": 1, "result": "AC", "execution_time": "2905 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A56DEA6A74393", "submission_order": 1, "result": "AC", "execution_time": "889 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A591A80DDCF21", "submission_order": 1, "result": "AC", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5924632373FB", "submission_order": 1, "result": "AC", "execution_time": "1882 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A599D664572B5", "submission_order": 1, "result": "AC", "execution_time": "1024 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5A48C3067DF3", "submission_order": 1, "result": "AC", "execution_time": "1529 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5A4B62102A99", "submission_order": 1, "result": "AC", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5BC19558F87F", "submission_order": 1, "result": "RE", "execution_time": "785 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ns\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5C650C33F764", "submission_order": 1, "result": "AC", "execution_time": "774 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5D7F56BD1B37", "submission_order": 1, "result": "AC", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5DD1D0EF73AF", "submission_order": 1, "result": "RE", "execution_time": "736 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.H(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5DD1D0EF73AF", "submission_order": 2, "result": "RE", "execution_time": "747 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.H(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5DD1D0EF73AF", "submission_order": 3, "result": "AC", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5F3817189C6E", "submission_order": 1, "result": "AC", "execution_time": "1143 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5F47170BE963", "submission_order": 1, "result": "RE", "execution_time": "1029 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.HGate\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5F47170BE963", "submission_order": 2, "result": "RE", "execution_time": "734 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.HGat(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5F47170BE963", "submission_order": 3, "result": "RE", "execution_time": "973 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5F47170BE963", "submission_order": 4, "result": "RE", "execution_time": "764 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5F47170BE963", "submission_order": 5, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5F63823F0B7D", "submission_order": 1, "result": "AC", "execution_time": "1366 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # |0> -> (1/sqrt(2)) (|0> + |1>) =: |+>\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5FA0BCF7D633", "submission_order": 1, "result": "RE", "execution_time": "1400 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\nreturn qc\n'''"}
{"problem": "QPC001_A1", "user": "A5FA0BCF7D633", "submission_order": 2, "result": "AC", "execution_time": "1525 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5FE8CA3D11A0", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A5FF6FDFF611A", "submission_order": 1, "result": "AC", "execution_time": "1066 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A606583DB85E4", "submission_order": 1, "result": "AC", "execution_time": "1538 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A607814402667", "submission_order": 1, "result": "RE", "execution_time": "738 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A607814402667", "submission_order": 2, "result": "WA", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A607814402667", "submission_order": 3, "result": "RE", "execution_time": "937 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A607814402667", "submission_order": 4, "result": "AC", "execution_time": "920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A60B308428D42", "submission_order": 1, "result": "AC", "execution_time": "859 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A60C846E05D6A", "submission_order": 1, "result": "AC", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A60D4229C86A5", "submission_order": 1, "result": "RE", "execution_time": "1605 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A60D4229C86A5", "submission_order": 2, "result": "AC", "execution_time": "1720 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6113E02850C6", "submission_order": 1, "result": "AC", "execution_time": "1875 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A61F75D454034", "submission_order": 1, "result": "AC", "execution_time": "822 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A61FDC99A3B87", "submission_order": 1, "result": "AC", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A62ED5C2165B9", "submission_order": 1, "result": "AC", "execution_time": "1436 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6339FA4ADAAE", "submission_order": 1, "result": "AC", "execution_time": "1514 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6363959929B6", "submission_order": 1, "result": "AC", "execution_time": "2161 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A649ACC7DA8A8", "submission_order": 1, "result": "RE", "execution_time": "804 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A649ACC7DA8A8", "submission_order": 2, "result": "AC", "execution_time": "1012 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A64FE32CDFEFA", "submission_order": 1, "result": "RE", "execution_time": "775 ms", "memory": "79 MiB", "code": "'''python\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A64FE32CDFEFA", "submission_order": 2, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A66C9F7F0EF25", "submission_order": 1, "result": "AC", "execution_time": "1451 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A67F56F8FBBAA", "submission_order": 1, "result": "AC", "execution_time": "928 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A681DD8D7B692", "submission_order": 1, "result": "AC", "execution_time": "1591 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A688EFE7DC5D0", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A689789070531", "submission_order": 1, "result": "AC", "execution_time": "1648 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A68E0004D0E9C", "submission_order": 1, "result": "AC", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A69E085F48211", "submission_order": 1, "result": "RE", "execution_time": "1366 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    gc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A69E085F48211", "submission_order": 2, "result": "AC", "execution_time": "1352 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6AB01FA05B70", "submission_order": 1, "result": "AC", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6D761FB3C66F", "submission_order": 1, "result": "AC", "execution_time": "1494 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0) \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6D92795E4A43", "submission_order": 1, "result": "AC", "execution_time": "1330 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6DF49B5574A7", "submission_order": 1, "result": "RE", "execution_time": "773 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(\n        HGate(),\n        [0]\n    )\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6DF49B5574A7", "submission_order": 2, "result": "RE", "execution_time": "786 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(\n        QuantumCircuit(),\n        [0]\n    )\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6DF49B5574A7", "submission_order": 3, "result": "AC", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6DF823A5BB8C", "submission_order": 1, "result": "AC", "execution_time": "1596 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A6F1C0CC0EBBB", "submission_order": 1, "result": "AC", "execution_time": "1758 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7031F8325A16", "submission_order": 1, "result": "RE", "execution_time": "1024 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7090AFA2C661", "submission_order": 1, "result": "WA", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7090AFA2C661", "submission_order": 2, "result": "WA", "execution_time": "866 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7090AFA2C661", "submission_order": 3, "result": "RE", "execution_time": "779 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7090AFA2C661", "submission_order": 4, "result": "RE", "execution_time": "805 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7090AFA2C661", "submission_order": 5, "result": "AC", "execution_time": "888 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7276FB365339", "submission_order": 1, "result": "AC", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A73028B3EC811", "submission_order": 1, "result": "RE", "execution_time": "785 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A73028B3EC811", "submission_order": 2, "result": "AC", "execution_time": "1017 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A740A2F38CA63", "submission_order": 1, "result": "AC", "execution_time": "1345 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A742AEDE7CA69", "submission_order": 1, "result": "AC", "execution_time": "1564 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7433D7581EA3", "submission_order": 1, "result": "AC", "execution_time": "1342 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A74496BA82BE5", "submission_order": 1, "result": "WA", "execution_time": "1677 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.h(0)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A74496BA82BE5", "submission_order": 2, "result": "AC", "execution_time": "1641 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A747D8EF8BDEB", "submission_order": 1, "result": "AC", "execution_time": "1530 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A74C93F774891", "submission_order": 1, "result": "AC", "execution_time": "2051 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A74E69B3510FB", "submission_order": 1, "result": "AC", "execution_time": "867 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A751CBA6C8136", "submission_order": 1, "result": "AC", "execution_time": "1229 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A758B70116F11", "submission_order": 1, "result": "AC", "execution_time": "1077 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A76177E600AF9", "submission_order": 1, "result": "AC", "execution_time": "797 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A777EF336F8AB", "submission_order": 1, "result": "RE", "execution_time": "845 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A777EF336F8AB", "submission_order": 2, "result": "AC", "execution_time": "941 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A78C7C7FC3E54", "submission_order": 1, "result": "AC", "execution_time": "2030 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A79423EAA821E", "submission_order": 1, "result": "AC", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7C17A8E82564", "submission_order": 1, "result": "AC", "execution_time": "826 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7C191A4E291D", "submission_order": 1, "result": "AC", "execution_time": "986 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7C65750BCFFA", "submission_order": 1, "result": "AC", "execution_time": "986 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7D56A2987AC9", "submission_order": 1, "result": "AC", "execution_time": "892 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7E718A0A62A4", "submission_order": 1, "result": "RE", "execution_time": "768 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = X(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7E718A0A62A4", "submission_order": 2, "result": "RE", "execution_time": "736 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.add_gate(X(0))\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7E718A0A62A4", "submission_order": 3, "result": "AC", "execution_time": "797 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7EAFD5BC6F97", "submission_order": 1, "result": "AC", "execution_time": "1480 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A7F7FA13FEF2E", "submission_order": 1, "result": "AC", "execution_time": "927 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8080EF693A4C", "submission_order": 1, "result": "AC", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A817B3538DBB5", "submission_order": 1, "result": "AC", "execution_time": "1636 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A81D4B791FE76", "submission_order": 1, "result": "AC", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A82224F9720DC", "submission_order": 1, "result": "AC", "execution_time": "1741 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A825ADF1A12A8", "submission_order": 1, "result": "AC", "execution_time": "1616 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A835C4A35BE27", "submission_order": 1, "result": "AC", "execution_time": "1364 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A83FF27B645EF", "submission_order": 1, "result": "AC", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8452F108E586", "submission_order": 1, "result": "WA", "execution_time": "827 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8452F108E586", "submission_order": 2, "result": "RE", "execution_time": "699 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8452F108E586", "submission_order": 3, "result": "AC", "execution_time": "799 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A859079088088", "submission_order": 1, "result": "AC", "execution_time": "824 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A85EEF977ACFB", "submission_order": 1, "result": "AC", "execution_time": "1428 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A862EB30CB015", "submission_order": 1, "result": "AC", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A86F091AD7E27", "submission_order": 1, "result": "AC", "execution_time": "1115 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A873445D735B1", "submission_order": 1, "result": "AC", "execution_time": "1276 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8741863B2FA1", "submission_order": 1, "result": "AC", "execution_time": "1849 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Hadamard gate to the qubit\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8909240A678F", "submission_order": 1, "result": "AC", "execution_time": "1117 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A893D3F7959E2", "submission_order": 1, "result": "AC", "execution_time": "1457 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A89DCB17A8019", "submission_order": 1, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A89E59E34CA3D", "submission_order": 1, "result": "AC", "execution_time": "896 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8ACDCC4916AF", "submission_order": 1, "result": "RE", "execution_time": "881 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    return qc.h()\n'''"}
{"problem": "QPC001_A1", "user": "A8ACDCC4916AF", "submission_order": 2, "result": "RE", "execution_time": "792 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    return qc.h(0)\n'''"}
{"problem": "QPC001_A1", "user": "A8ACDCC4916AF", "submission_order": 3, "result": "AC", "execution_time": "935 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8AD54340300E", "submission_order": 1, "result": "AC", "execution_time": "1379 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8AE8B30325FB", "submission_order": 1, "result": "RE", "execution_time": "1736 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8AE8B30325FB", "submission_order": 2, "result": "RE", "execution_time": "1742 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.g(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8AE8B30325FB", "submission_order": 3, "result": "RE", "execution_time": "1771 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8AE8B30325FB", "submission_order": 4, "result": "RE", "execution_time": "1742 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8AE8B30325FB", "submission_order": 5, "result": "RE", "execution_time": "1793 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.g(1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8AE8B30325FB", "submission_order": 6, "result": "AC", "execution_time": "1851 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n \n    qc.append(HGate(), [0])\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8CB85D6317CD", "submission_order": 1, "result": "AC", "execution_time": "1432 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8D088B781830", "submission_order": 1, "result": "AC", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8D1D8E343597", "submission_order": 1, "result": "AC", "execution_time": "1895 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8E48259FDD07", "submission_order": 1, "result": "AC", "execution_time": "1525 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8EBFE1D9B594", "submission_order": 1, "result": "AC", "execution_time": "1511 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8F628320D1B6", "submission_order": 1, "result": "AC", "execution_time": "1625 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A8F8E58E2CB77", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC001_A1", "user": "A8F8E58E2CB77", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n\nif __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC001_A1", "user": "A8F8E58E2CB77", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n\nif __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    qc = solve()\n    print(Statevector(qc))\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A1", "user": "A8F8E58E2CB77", "submission_order": 4, "result": "AC", "execution_time": "1926 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A1", "user": "A8FF94C668EA7", "submission_order": 1, "result": "AC", "execution_time": "1165 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A900029ABA0FF", "submission_order": 1, "result": "AC", "execution_time": "1399 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A909604242A16", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    from qiskit import QuantumRegister, ClassicalRegister\n\n    qr = QuantumRegister(1)\n    cr = ClassicalRegister(1)\n    qc = QuantumCircuit(qr, cr)\n\n    qc.h(0)\n    qc.measure(0, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A909604242A16", "submission_order": 2, "result": "AC", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A91A8995B45FC", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n \n \n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A1", "user": "A91A8995B45FC", "submission_order": 2, "result": "AC", "execution_time": "1351 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n \n \n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A1", "user": "A91E7140FC6F7", "submission_order": 1, "result": "AC", "execution_time": "1331 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A92E9FB7E466D", "submission_order": 1, "result": "AC", "execution_time": "1758 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9338B82CA15A", "submission_order": 1, "result": "WA", "execution_time": "1339 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9338B82CA15A", "submission_order": 2, "result": "WA", "execution_time": "1399 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9338B82CA15A", "submission_order": 3, "result": "AC", "execution_time": "1429 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9400116298CA", "submission_order": 1, "result": "AC", "execution_time": "978 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A94A4CF1E0356", "submission_order": 1, "result": "AC", "execution_time": "821 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A94F6B8B94DBB", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A95EF21B61216", "submission_order": 1, "result": "AC", "execution_time": "955 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A95FE1B3F8A89", "submission_order": 1, "result": "RE", "execution_time": "1635 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.H(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A95FE1B3F8A89", "submission_order": 2, "result": "RE", "execution_time": "1620 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.Hadamard(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A95FE1B3F8A89", "submission_order": 3, "result": "AC", "execution_time": "1645 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A96F5685A7C8C", "submission_order": 1, "result": "RE", "execution_time": "786 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A96F5685A7C8C", "submission_order": 2, "result": "AC", "execution_time": "868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A977CC18389DA", "submission_order": 1, "result": "AC", "execution_time": "1141 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A98312234EF77", "submission_order": 1, "result": "RE", "execution_time": "1488 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc=qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A98312234EF77", "submission_order": 2, "result": "RE", "execution_time": "751 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc=qc.g(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A98312234EF77", "submission_order": 3, "result": "RE", "execution_time": "778 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A98312234EF77", "submission_order": 4, "result": "AC", "execution_time": "966 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9834D96130A1", "submission_order": 1, "result": "RE", "execution_time": "1478 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9834D96130A1", "submission_order": 2, "result": "AC", "execution_time": "1218 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A98A0DB9A5073", "submission_order": 1, "result": "WA", "execution_time": "1128 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A98A0DB9A5073", "submission_order": 2, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9A3F14514734", "submission_order": 1, "result": "AC", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # Create a Quantum Circuit acting on the q register\n\n    # Add a H gate on qubit 0\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9AB70FC3106C", "submission_order": 1, "result": "AC", "execution_time": "1073 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9B66EA6B784D", "submission_order": 1, "result": "AC", "execution_time": "897 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9B6B3EEE4831", "submission_order": 1, "result": "AC", "execution_time": "1482 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9C34003C826E", "submission_order": 1, "result": "RE", "execution_time": "1387 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.h[0]\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9CBFFD356D59", "submission_order": 1, "result": "AC", "execution_time": "1703 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9DE22EF14835", "submission_order": 1, "result": "AC", "execution_time": "1860 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "A9EA92071E316", "submission_order": 1, "result": "AC", "execution_time": "1058 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # NOT + hadamard = minus state\n    qc.h(0)\n\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(qc)\n'''"}
{"problem": "QPC001_A1", "user": "AA05A9BDC2F50", "submission_order": 1, "result": "AC", "execution_time": "985 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA0F9FF28FF36", "submission_order": 1, "result": "AC", "execution_time": "1230 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n \n    qc.append(HGate(), [0])\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA11D0E7807C1", "submission_order": 1, "result": "AC", "execution_time": "978 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA1D09F728B0A", "submission_order": 1, "result": "AC", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA28832B9D6A1", "submission_order": 1, "result": "AC", "execution_time": "819 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA2B3C2C1DD7C", "submission_order": 1, "result": "AC", "execution_time": "922 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0);\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA30941E0051A", "submission_order": 1, "result": "RE", "execution_time": "700 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA30941E0051A", "submission_order": 2, "result": "RE", "execution_time": "786 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA30941E0051A", "submission_order": 3, "result": "AC", "execution_time": "806 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA359900110A1", "submission_order": 1, "result": "AC", "execution_time": "1171 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA3BDEB60384E", "submission_order": 1, "result": "AC", "execution_time": "909 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA3C54ED74839", "submission_order": 1, "result": "AC", "execution_time": "1761 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA4336233A687", "submission_order": 1, "result": "AC", "execution_time": "1325 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA49C1EA95ECE", "submission_order": 1, "result": "WA", "execution_time": "1620 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA49C1EA95ECE", "submission_order": 2, "result": "AC", "execution_time": "1652 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA5365CAA2A09", "submission_order": 1, "result": "AC", "execution_time": "806 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # アダマールゲートを1量子ビットに適用\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA582A5598D67", "submission_order": 1, "result": "WA", "execution_time": "1385 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n \n    qc.x(0)\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA582A5598D67", "submission_order": 2, "result": "AC", "execution_time": "1374 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA60889A1105B", "submission_order": 1, "result": "AC", "execution_time": "955 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA68B390D3F30", "submission_order": 1, "result": "AC", "execution_time": "931 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA7072A939B5E", "submission_order": 1, "result": "AC", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA7A9D13A0046", "submission_order": 1, "result": "AC", "execution_time": "1276 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    # Apply Hadamard gate to the 1st qubit (index 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA7D8F8837C8C", "submission_order": 1, "result": "AC", "execution_time": "1001 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA81BEA3BB53D", "submission_order": 1, "result": "AC", "execution_time": "1079 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA8BB2AEF362B", "submission_order": 1, "result": "AC", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA97EB2A28B86", "submission_order": 1, "result": "RE", "execution_time": "1221 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA97EB2A28B86", "submission_order": 2, "result": "RE", "execution_time": "804 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AA9A31343E5D6", "submission_order": 1, "result": "AC", "execution_time": "1574 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    A = QuantumCircuit(1)\n    A.h(0)\n    return A\n'''"}
{"problem": "QPC001_A1", "user": "AA9C333F13BAE", "submission_order": 1, "result": "AC", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAA994924C050", "submission_order": 1, "result": "RE", "execution_time": "781 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAA994924C050", "submission_order": 2, "result": "AC", "execution_time": "831 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAC2D8384EFF7", "submission_order": 1, "result": "AC", "execution_time": "1756 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAC3C06BB5546", "submission_order": 1, "result": "AC", "execution_time": "1969 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AACF42A92D4E2", "submission_order": 1, "result": "AC", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAD5BDACFAC6A", "submission_order": 1, "result": "AC", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AADA451A864F8", "submission_order": 1, "result": "AC", "execution_time": "1372 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAE036EBD45A3", "submission_order": 1, "result": "AC", "execution_time": "1408 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAE0BA4A3F1A9", "submission_order": 1, "result": "WA", "execution_time": "1379 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAE0BA4A3F1A9", "submission_order": 2, "result": "AC", "execution_time": "1346 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAF4F147C62D4", "submission_order": 1, "result": "AC", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Hゲート（アダマールゲート）を適用\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAF67A7CE9B18", "submission_order": 1, "result": "AC", "execution_time": "1436 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAFA0E0A59034", "submission_order": 1, "result": "AC", "execution_time": "1379 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AAFEA4F4FC39B", "submission_order": 1, "result": "AC", "execution_time": "1364 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB04D85CC8E89", "submission_order": 1, "result": "AC", "execution_time": "813 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB0CA1F44AC7C", "submission_order": 1, "result": "AC", "execution_time": "859 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB21AF83373F9", "submission_order": 1, "result": "AC", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB41551F28D34", "submission_order": 1, "result": "AC", "execution_time": "1297 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB4923CC25C9B", "submission_order": 1, "result": "RE", "execution_time": "801 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB4923CC25C9B", "submission_order": 2, "result": "RE", "execution_time": "813 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(qc[1])\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB4923CC25C9B", "submission_order": 3, "result": "AC", "execution_time": "1047 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB4D633DDB77C", "submission_order": 1, "result": "AC", "execution_time": "962 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB4E8B2A563F9", "submission_order": 1, "result": "AC", "execution_time": "815 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB57E86F7AE16", "submission_order": 1, "result": "AC", "execution_time": "1345 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB594190FE464", "submission_order": 1, "result": "AC", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB61358A3F023", "submission_order": 1, "result": "RE", "execution_time": "1024 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB61358A3F023", "submission_order": 2, "result": "AC", "execution_time": "1043 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB6276BF39550", "submission_order": 1, "result": "RE", "execution_time": "778 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB6276BF39550", "submission_order": 2, "result": "AC", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB6A55D9F6142", "submission_order": 1, "result": "AC", "execution_time": "916 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB72F497CDB3F", "submission_order": 1, "result": "AC", "execution_time": "960 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB7A4F7AC9302", "submission_order": 1, "result": "AC", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB8A3953875F9", "submission_order": 1, "result": "RE", "execution_time": "1673 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    myhgate = HGate()\n    qc.append(myhgate, [0])\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB8A3953875F9", "submission_order": 2, "result": "AC", "execution_time": "1897 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    myhgate = HGate()\n    qc.append(myhgate, [0])\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AB917FACA8AFB", "submission_order": 1, "result": "AC", "execution_time": "892 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABA91AF64DBE9", "submission_order": 1, "result": "AC", "execution_time": "1420 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # Apply Hadamard gate to prepare |+⟩ from |0⟩\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABAB0AC9BE715", "submission_order": 1, "result": "AC", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABAC07A8A9F3F", "submission_order": 1, "result": "AC", "execution_time": "1736 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABC7C356F1148", "submission_order": 1, "result": "AC", "execution_time": "1657 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABC92254343D6", "submission_order": 1, "result": "AC", "execution_time": "2034 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABC94DA033A27", "submission_order": 1, "result": "AC", "execution_time": "1561 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABCA77EE9E277", "submission_order": 1, "result": "RE", "execution_time": "774 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.H(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABCA77EE9E277", "submission_order": 2, "result": "AC", "execution_time": "956 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABCDAE57D0ED3", "submission_order": 1, "result": "AC", "execution_time": "1112 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABDC0EC4B6063", "submission_order": 1, "result": "AC", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABE46ED7419F2", "submission_order": 1, "result": "AC", "execution_time": "932 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABEB363BF7DB7", "submission_order": 1, "result": "AC", "execution_time": "1384 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABF5120E58195", "submission_order": 1, "result": "AC", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABF66137018D6", "submission_order": 1, "result": "AC", "execution_time": "889 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABFDEAE30EED0", "submission_order": 1, "result": "RE", "execution_time": "1423 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    from qiskit import QuantumCircuit\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ABFDEAE30EED0", "submission_order": 2, "result": "AC", "execution_time": "1384 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC0FF88C88C0C", "submission_order": 1, "result": "RE", "execution_time": "744 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.H(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC0FF88C88C0C", "submission_order": 2, "result": "AC", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC1297D815AC6", "submission_order": 1, "result": "AC", "execution_time": "1581 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC1862971859B", "submission_order": 1, "result": "RE", "execution_time": "875 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc.h(0)\n'''"}
{"problem": "QPC001_A1", "user": "AC1862971859B", "submission_order": 2, "result": "AC", "execution_time": "813 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC19137BF9417", "submission_order": 1, "result": "RE", "execution_time": "811 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC19137BF9417", "submission_order": 2, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC1DFE1D692A3", "submission_order": 1, "result": "AC", "execution_time": "1303 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC28B2AD17FF9", "submission_order": 1, "result": "AC", "execution_time": "1852 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC31F14724F0A", "submission_order": 1, "result": "AC", "execution_time": "1311 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC3DB44FFFB7D", "submission_order": 1, "result": "AC", "execution_time": "1468 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC4CB44763B45", "submission_order": 1, "result": "WA", "execution_time": "1586 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC4CB44763B45", "submission_order": 2, "result": "AC", "execution_time": "1882 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC4E918B3B64D", "submission_order": 1, "result": "AC", "execution_time": "1051 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC57A0A360E76", "submission_order": 1, "result": "AC", "execution_time": "1447 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC5AF46D92262", "submission_order": 1, "result": "AC", "execution_time": "1624 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC625D5604F31", "submission_order": 1, "result": "AC", "execution_time": "1137 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC6D18D3ABFBD", "submission_order": 1, "result": "AC", "execution_time": "851 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(1)\n  qc.h(0)\n  return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC78A489F5643", "submission_order": 1, "result": "AC", "execution_time": "1492 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC82CF5CA0972", "submission_order": 1, "result": "AC", "execution_time": "1281 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC88A70EC8D3D", "submission_order": 1, "result": "AC", "execution_time": "1381 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC89729843CE8", "submission_order": 1, "result": "AC", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    # Hadamardゲートを適用してプラス状態を生成\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC89DA5EED8AE", "submission_order": 1, "result": "AC", "execution_time": "1643 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC8ACE8E1DC7B", "submission_order": 1, "result": "AC", "execution_time": "1432 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AC9C460B2DFB9", "submission_order": 1, "result": "AC", "execution_time": "826 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACADC02BA50F6", "submission_order": 1, "result": "AC", "execution_time": "1538 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACB35BBEFA244", "submission_order": 1, "result": "AC", "execution_time": "1738 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    # Apply Hadamard gate to the 1st qubit (index 0)\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACBAF96DE9EA7", "submission_order": 1, "result": "AC", "execution_time": "1345 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACD51643A3FBE", "submission_order": 1, "result": "AC", "execution_time": "797 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACDB001795CED", "submission_order": 1, "result": "AC", "execution_time": "1133 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n \n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACDB07F20C185", "submission_order": 1, "result": "WA", "execution_time": "1340 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACDB488C5C1F7", "submission_order": 1, "result": "AC", "execution_time": "868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACEF69111AA78", "submission_order": 1, "result": "AC", "execution_time": "1350 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACFA37F7C5320", "submission_order": 1, "result": "AC", "execution_time": "818 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ACFBEAAC9ABDB", "submission_order": 1, "result": "AC", "execution_time": "707 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD08DD975F26D", "submission_order": 1, "result": "AC", "execution_time": "1580 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD09CF511F3BF", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD0AFE33621A3", "submission_order": 1, "result": "RE", "execution_time": "1726 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD0AFE33621A3", "submission_order": 2, "result": "AC", "execution_time": "1936 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD10058765C6E", "submission_order": 1, "result": "AC", "execution_time": "1045 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD173576D160D", "submission_order": 1, "result": "WA", "execution_time": "1377 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD173576D160D", "submission_order": 2, "result": "AC", "execution_time": "1365 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD1D17107F070", "submission_order": 1, "result": "AC", "execution_time": "892 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD2B9372404BF", "submission_order": 1, "result": "AC", "execution_time": "867 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(1)\n\tqc.h(0)\n\treturn qc\n'''"}
{"problem": "QPC001_A1", "user": "AD3089B2CDDF4", "submission_order": 1, "result": "AC", "execution_time": "990 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD314660F1D0B", "submission_order": 1, "result": "RE", "execution_time": "1323 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.H(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD314660F1D0B", "submission_order": 2, "result": "RE", "execution_time": "1283 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(pi/2, 0, pi, 0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD314660F1D0B", "submission_order": 3, "result": "AC", "execution_time": "1381 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(HGate(), [0])\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD3310D22A6FF", "submission_order": 1, "result": "AC", "execution_time": "1459 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD3702D4371C0", "submission_order": 1, "result": "RE", "execution_time": "758 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(o)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD3702D4371C0", "submission_order": 2, "result": "AC", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD3A93F851C55", "submission_order": 1, "result": "AC", "execution_time": "1075 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD4DF9B19908E", "submission_order": 1, "result": "AC", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD50B6B9297AC", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD74FBE223C1B", "submission_order": 1, "result": "AC", "execution_time": "1427 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD80DBAC23AB5", "submission_order": 1, "result": "AC", "execution_time": "1519 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD9853FB888BE", "submission_order": 1, "result": "AC", "execution_time": "1082 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD9961CED9093", "submission_order": 1, "result": "WA", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD9961CED9093", "submission_order": 2, "result": "AC", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD9FB110E5F81", "submission_order": 1, "result": "RE", "execution_time": "1831 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AD9FB110E5F81", "submission_order": 2, "result": "AC", "execution_time": "2428 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADA85959E39AE", "submission_order": 1, "result": "AC", "execution_time": "1069 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADA9559A91C22", "submission_order": 1, "result": "AC", "execution_time": "1603 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADA9B5A940E0F", "submission_order": 1, "result": "AC", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADB38751AE159", "submission_order": 1, "result": "AC", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADD117378ED10", "submission_order": 1, "result": "AC", "execution_time": "1018 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADD621C21E84B", "submission_order": 1, "result": "AC", "execution_time": "1858 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADD9353C8702E", "submission_order": 1, "result": "AC", "execution_time": "1950 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADEAB863E2206", "submission_order": 1, "result": "AC", "execution_time": "2029 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADEC022B4B7BF", "submission_order": 1, "result": "AC", "execution_time": "1019 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADED662AB11A7", "submission_order": 1, "result": "WA", "execution_time": "814 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADED662AB11A7", "submission_order": 2, "result": "AC", "execution_time": "1125 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADF58DF0F416F", "submission_order": 1, "result": "AC", "execution_time": "2088 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "ADFF32AB526E5", "submission_order": 1, "result": "AC", "execution_time": "935 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE059380940E1", "submission_order": 1, "result": "AC", "execution_time": "1810 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE0DCD8B28002", "submission_order": 1, "result": "AC", "execution_time": "1133 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE0E8E42F06A2", "submission_order": 1, "result": "AC", "execution_time": "1895 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE12130F446C7", "submission_order": 1, "result": "AC", "execution_time": "851 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE1496D570E19", "submission_order": 1, "result": "AC", "execution_time": "1880 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE1F929806ABC", "submission_order": 1, "result": "AC", "execution_time": "890 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE22148F102C8", "submission_order": 1, "result": "AC", "execution_time": "885 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE3CBED32718D", "submission_order": 1, "result": "AC", "execution_time": "1031 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE3EE335FBAE3", "submission_order": 1, "result": "RE", "execution_time": "1365 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc.h(0)\n'''"}
{"problem": "QPC001_A1", "user": "AE3EE335FBAE3", "submission_order": 2, "result": "AC", "execution_time": "1419 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE4E9C07AFD51", "submission_order": 1, "result": "RE", "execution_time": "1171 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    cq.H()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE4E9C07AFD51", "submission_order": 2, "result": "RE", "execution_time": "1558 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.H()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE4E9C07AFD51", "submission_order": 3, "result": "RE", "execution_time": "1501 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    q.h()\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE4E9C07AFD51", "submission_order": 4, "result": "RE", "execution_time": "1485 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    q.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE4E9C07AFD51", "submission_order": 5, "result": "AC", "execution_time": "1531 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE5AE6C804716", "submission_order": 1, "result": "RE", "execution_time": "809 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.H(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE5AE6C804716", "submission_order": 2, "result": "AC", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE5C8B0B01057", "submission_order": 1, "result": "AC", "execution_time": "965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE600E85D043E", "submission_order": 1, "result": "RE", "execution_time": "1422 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.HGate(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE600E85D043E", "submission_order": 2, "result": "RE", "execution_time": "1422 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.HGate(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE600E85D043E", "submission_order": 3, "result": "AC", "execution_time": "1534 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE63CA188A14B", "submission_order": 1, "result": "AC", "execution_time": "823 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE76307BD3647", "submission_order": 1, "result": "AC", "execution_time": "1639 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE7696B2B6064", "submission_order": 1, "result": "AC", "execution_time": "1515 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE7E00D3C23D1", "submission_order": 1, "result": "AC", "execution_time": "1331 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE9D6BAD015D3", "submission_order": 1, "result": "QLE", "execution_time": "745 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE9D6BAD015D3", "submission_order": 2, "result": "RE", "execution_time": "767 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE9D6BAD015D3", "submission_order": 3, "result": "AC", "execution_time": "812 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE9EC4AFE45B0", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import SparsePauliOp\nfrom qiskit.transpiler.preset_passmanagers import generate_preset_pass_manager\nfrom qiskit_ibm_runtime import EstimatorV2 as Estimator\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE9EC4AFE45B0", "submission_order": 2, "result": "AC", "execution_time": "1550 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AE9FA75226DA5", "submission_order": 1, "result": "AC", "execution_time": "1758 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEA3D0CA332EC", "submission_order": 1, "result": "AC", "execution_time": "1304 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEAB2C34CC647", "submission_order": 1, "result": "AC", "execution_time": "1065 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEAB48CB1EE6E", "submission_order": 1, "result": "AC", "execution_time": "1473 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEBD9233BACAB", "submission_order": 1, "result": "AC", "execution_time": "1560 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEC39E4DC3AAA", "submission_order": 1, "result": "AC", "execution_time": "911 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AECEA41AB6A99", "submission_order": 1, "result": "WA", "execution_time": "960 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AECEA41AB6A99", "submission_order": 2, "result": "AC", "execution_time": "870 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEDBCC49A34B3", "submission_order": 1, "result": "AC", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEDD91FF4E8C7", "submission_order": 1, "result": "WA", "execution_time": "1516 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEE95C27DC8BE", "submission_order": 1, "result": "AC", "execution_time": "2247 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEEB7B1F63F98", "submission_order": 1, "result": "AC", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEF12B20B7C94", "submission_order": 1, "result": "AC", "execution_time": "1384 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AEFCFDAB89104", "submission_order": 1, "result": "AC", "execution_time": "1135 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF12CEB455C4D", "submission_order": 1, "result": "AC", "execution_time": "1542 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF14D945A7D71", "submission_order": 1, "result": "AC", "execution_time": "1599 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF15E80351190", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF15E80351190", "submission_order": 2, "result": "AC", "execution_time": "1603 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF17E6CFCBF35", "submission_order": 1, "result": "RE", "execution_time": "775 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF17E6CFCBF35", "submission_order": 2, "result": "AC", "execution_time": "1674 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF1C977D8045F", "submission_order": 1, "result": "RE", "execution_time": "1955 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.HGate(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF1C977D8045F", "submission_order": 2, "result": "RE", "execution_time": "768 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF1C977D8045F", "submission_order": 3, "result": "AC", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF26016A7DFB9", "submission_order": 1, "result": "AC", "execution_time": "1639 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF28AF4965563", "submission_order": 1, "result": "AC", "execution_time": "2673 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(\n        HGate(),\n        [0],\n    )\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF32BDCD4DE21", "submission_order": 1, "result": "WA", "execution_time": "931 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF32BDCD4DE21", "submission_order": 2, "result": "AC", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF369A5957E28", "submission_order": 1, "result": "AC", "execution_time": "874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF38B16CF87A7", "submission_order": 1, "result": "AC", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF3A8705DE099", "submission_order": 1, "result": "AC", "execution_time": "956 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)  # 0番目の量子ビットにHゲートを適用\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF3F0837C0766", "submission_order": 1, "result": "AC", "execution_time": "1940 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF3F9DBCA6A78", "submission_order": 1, "result": "AC", "execution_time": "1652 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF444FADDBFEF", "submission_order": 1, "result": "AC", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF477DDC8F5A8", "submission_order": 1, "result": "AC", "execution_time": "809 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF51E7194282D", "submission_order": 1, "result": "RE", "execution_time": "776 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.H(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF51E7194282D", "submission_order": 2, "result": "RE", "execution_time": "864 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF51E7194282D", "submission_order": 3, "result": "AC", "execution_time": "959 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF580256068B6", "submission_order": 1, "result": "AC", "execution_time": "1059 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF6EE1B80C928", "submission_order": 1, "result": "AC", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF710C9397E85", "submission_order": 1, "result": "RE", "execution_time": "766 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.g(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF710C9397E85", "submission_order": 2, "result": "RE", "execution_time": "929 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.g(0)\n    qc.measure(1, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF710C9397E85", "submission_order": 3, "result": "RE", "execution_time": "907 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.g(0)\n    qc.measure(0, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF710C9397E85", "submission_order": 4, "result": "RE", "execution_time": "822 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.g(0)\n    qc.measure(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF710C9397E85", "submission_order": 5, "result": "RE", "execution_time": "778 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.g(0)\n    qc.measure(range(1), range(1))\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF710C9397E85", "submission_order": 6, "result": "AC", "execution_time": "837 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF72C6976D864", "submission_order": 1, "result": "AC", "execution_time": "809 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)    \n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF9427DF2E807", "submission_order": 1, "result": "AC", "execution_time": "815 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF99F5B322364", "submission_order": 1, "result": "AC", "execution_time": "2498 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AF9B9AFCE34A8", "submission_order": 1, "result": "AC", "execution_time": "1664 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFA72BC8BF720", "submission_order": 1, "result": "AC", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFA811449542E", "submission_order": 1, "result": "AC", "execution_time": "1491 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFAC1434390C8", "submission_order": 1, "result": "AC", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFBE2E80461DD", "submission_order": 1, "result": "AC", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 1, "result": "WA", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 2, "result": "RE", "execution_time": "1058 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    alpha = \n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 3, "result": "RE", "execution_time": "761 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    alpha = \n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 4, "result": "RE", "execution_time": "807 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 5, "result": "WA", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 6, "result": "RE", "execution_time": "771 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    gate = H[0]\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 7, "result": "RE", "execution_time": "1075 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    state = QuantumCircuit(1)\n    gate = H(0)\n    gate.update_quantum_state(state)\n    return QuantumCircuit(state=state)\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 8, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom library.svsim import H\n\n\ndef solve() -> QuantumCircuit:\n    state = QuantumCircuit(1)\n    gate = H(0)\n    gate.update_quantum_state(state)\n    return QuantumCircuit(state=state)\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 9, "result": "RE", "execution_time": "764 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    state = QuantumCircuit(1)\n    gate = HGate(0)\n    gate.update_quantum_state(state)\n    return QuantumCircuit(state=state)\n'''"}
{"problem": "QPC001_A1", "user": "AFC93AE1F9BB7", "submission_order": 10, "result": "AC", "execution_time": "1019 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.append(HGate(),[0])\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFC9CC8B4A510", "submission_order": 1, "result": "AC", "execution_time": "862 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFD011959FC25", "submission_order": 1, "result": "AC", "execution_time": "1449 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFD2C0FC00942", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(HGate(), 0[]) \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFD2C0FC00942", "submission_order": 2, "result": "AC", "execution_time": "1788 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(HGate(), [0]) \n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFD488FDC211B", "submission_order": 1, "result": "AC", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFE0D388AD7F7", "submission_order": 1, "result": "AC", "execution_time": "950 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFE3163EA9586", "submission_order": 1, "result": "AC", "execution_time": "813 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFF80CF1DF2F2", "submission_order": 1, "result": "AC", "execution_time": "824 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFF8D0E5407D3", "submission_order": 1, "result": "RE", "execution_time": "786 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFF8D0E5407D3", "submission_order": 2, "result": "WA", "execution_time": "1128 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFF8D0E5407D3", "submission_order": 3, "result": "RE", "execution_time": "781 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFF8D0E5407D3", "submission_order": 4, "result": "AC", "execution_time": "815 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFFB6567D99A4", "submission_order": 1, "result": "AC", "execution_time": "837 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A1", "user": "AFFEF09ED0B99", "submission_order": 1, "result": "AC", "execution_time": "1074 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0017584CBCC1", "submission_order": 1, "result": "AC", "execution_time": "1393 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0029222B21CC", "submission_order": 1, "result": "RE", "execution_time": "1406 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0029222B21CC", "submission_order": 2, "result": "AC", "execution_time": "1700 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A004008A6EF17", "submission_order": 1, "result": "AC", "execution_time": "1637 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A009EE85465BF", "submission_order": 1, "result": "AC", "execution_time": "1031 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A00A404EBD348", "submission_order": 1, "result": "AC", "execution_time": "1591 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A00C7D928F955", "submission_order": 1, "result": "AC", "execution_time": "2102 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A00F75E2B1743", "submission_order": 1, "result": "RE", "execution_time": "815 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A00F75E2B1743", "submission_order": 2, "result": "AC", "execution_time": "960 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A024C22F7F710", "submission_order": 1, "result": "AC", "execution_time": "1083 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A02E10143B38F", "submission_order": 1, "result": "AC", "execution_time": "1158 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A03333F3EA0BE", "submission_order": 1, "result": "AC", "execution_time": "1882 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A03804E73CEA4", "submission_order": 1, "result": "AC", "execution_time": "960 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A05B070F15C51", "submission_order": 1, "result": "RE", "execution_time": "1286 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc = qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A05B070F15C51", "submission_order": 2, "result": "AC", "execution_time": "1559 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A05DE93BA0CF2", "submission_order": 1, "result": "AC", "execution_time": "1705 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0A560C6C8BA3", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport qiskit\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0A560C6C8BA3", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport qiskit\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0A560C6C8BA3", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport qiskit\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(0, n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0A560C6C8BA3", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport qiskit\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0A560C6C8BA3", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport qiskit\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0A560C6C8BA3", "submission_order": 6, "result": "AC", "execution_time": "1489 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0A97763A0CC3", "submission_order": 1, "result": "AC", "execution_time": "1679 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0B5BB59142C4", "submission_order": 1, "result": "AC", "execution_time": "1047 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0BDD44D0153E", "submission_order": 1, "result": "AC", "execution_time": "1032 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0C6442BB3CD9", "submission_order": 1, "result": "AC", "execution_time": "1572 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0C8694E27500", "submission_order": 1, "result": "RE", "execution_time": "970 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0C8694E27500", "submission_order": 2, "result": "AC", "execution_time": "1013 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0CCB65C9B0FB", "submission_order": 1, "result": "AC", "execution_time": "1830 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n      qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0D150FC4D152", "submission_order": 1, "result": "AC", "execution_time": "1098 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0D66C3DB8C10", "submission_order": 1, "result": "AC", "execution_time": "1068 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0DD0ECD4C7BA", "submission_order": 1, "result": "AC", "execution_time": "2622 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0E09CDA52EC2", "submission_order": 1, "result": "AC", "execution_time": "1771 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0E5515C31F00", "submission_order": 1, "result": "WA", "execution_time": "1426 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(0)\n        \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0E5515C31F00", "submission_order": 2, "result": "AC", "execution_time": "1699 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0E602703E961", "submission_order": 1, "result": "RE", "execution_time": "816 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0E602703E961", "submission_order": 2, "result": "AC", "execution_time": "1196 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0E6252E7A16A", "submission_order": 1, "result": "AC", "execution_time": "2360 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0E6FD96C44A4", "submission_order": 1, "result": "AC", "execution_time": "1736 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A2", "user": "A0EFFDA96ECA9", "submission_order": 1, "result": "AC", "execution_time": "1397 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0F21799F2E08", "submission_order": 1, "result": "AC", "execution_time": "1638 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0F5057E07B6A", "submission_order": 1, "result": "RE", "execution_time": "831 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A0F5057E07B6A", "submission_order": 2, "result": "AC", "execution_time": "1712 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1032FAD5F181", "submission_order": 1, "result": "AC", "execution_time": "974 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A10601D2F54A6", "submission_order": 1, "result": "AC", "execution_time": "2005 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A2", "user": "A10D0C7AAA7F8", "submission_order": 1, "result": "AC", "execution_time": "1296 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A10DC3B39C36E", "submission_order": 1, "result": "AC", "execution_time": "940 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A114A565CC525", "submission_order": 1, "result": "AC", "execution_time": "980 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A128D3C55F312", "submission_order": 1, "result": "AC", "execution_time": "1431 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A131601C12F82", "submission_order": 1, "result": "AC", "execution_time": "1102 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n): qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A13B6A68ED886", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A14462CEACF6A", "submission_order": 1, "result": "AC", "execution_time": "1064 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1460BB6DA1BB", "submission_order": 1, "result": "AC", "execution_time": "1924 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # n = int(input())\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A149BA4A5943B", "submission_order": 1, "result": "AC", "execution_time": "1982 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A158D916FF2ED", "submission_order": 1, "result": "AC", "execution_time": "1701 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A15B7BB8022D8", "submission_order": 1, "result": "AC", "execution_time": "1229 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A160A4B397C37", "submission_order": 1, "result": "AC", "execution_time": "1199 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A16268854E938", "submission_order": 1, "result": "AC", "execution_time": "1555 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A163C3447D121", "submission_order": 1, "result": "AC", "execution_time": "1281 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A16E78B66BBBC", "submission_order": 1, "result": "RE", "execution_time": "1099 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i range(n):\n        qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A16E78B66BBBC", "submission_order": 2, "result": "AC", "execution_time": "1174 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A180091CB993E", "submission_order": 1, "result": "AC", "execution_time": "1451 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A183CC6AEF31C", "submission_order": 1, "result": "WA", "execution_time": "2129 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A183CC6AEF31C", "submission_order": 2, "result": "AC", "execution_time": "2102 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A18CFB76F4069", "submission_order": 1, "result": "AC", "execution_time": "1620 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n     \n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A192CF37DD402", "submission_order": 1, "result": "AC", "execution_time": "2601 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1991D35BF626", "submission_order": 1, "result": "AC", "execution_time": "1370 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A19B0641A6706", "submission_order": 1, "result": "RE", "execution_time": "1547 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0).h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A19B0641A6706", "submission_order": 2, "result": "AC", "execution_time": "1911 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1A7B59B45378", "submission_order": 1, "result": "AC", "execution_time": "1239 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1B0BD3865F98", "submission_order": 1, "result": "RE", "execution_time": "1971 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1B0BD3865F98", "submission_order": 2, "result": "AC", "execution_time": "2361 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1C7E31A23F1C", "submission_order": 1, "result": "AC", "execution_time": "2022 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1CD2170BEE19", "submission_order": 1, "result": "RE", "execution_time": "1454 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1D29E3233DD3", "submission_order": 1, "result": "RE", "execution_time": "2106 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1D29E3233DD3", "submission_order": 2, "result": "WA", "execution_time": "1768 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1D29E3233DD3", "submission_order": 3, "result": "WA", "execution_time": "1680 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1D29E3233DD3", "submission_order": 4, "result": "AC", "execution_time": "2249 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1D648885468B", "submission_order": 1, "result": "WA", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for j in range(1, n):\n        qc.cx(j-1, j)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1DE8CE74DA86", "submission_order": 1, "result": "AC", "execution_time": "1431 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1E79D4C5B165", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1ECEE69142D5", "submission_order": 1, "result": "RE", "execution_time": "853 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1ECEE69142D5", "submission_order": 2, "result": "AC", "execution_time": "1081 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1F3B47EC3B79", "submission_order": 1, "result": "AC", "execution_time": "1491 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1F7C2BE9D7D8", "submission_order": 1, "result": "AC", "execution_time": "1980 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A1F82D35598BD", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom IPython.display import display\nfrom qiskit import QuantumCircuit\nfrom qiskit.primitives import Sampler\nfrom qiskit.visualization import plot_histogram\n \ndef solve(n: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.h(i)\n\treturn qc\n'''"}
{"problem": "QPC001_A2", "user": "A1F82D35598BD", "submission_order": 2, "result": "AC", "execution_time": "1158 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.h(i)\n\treturn qc\n'''"}
{"problem": "QPC001_A2", "user": "A218B43BA0979", "submission_order": 1, "result": "WA", "execution_time": "940 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A218B43BA0979", "submission_order": 2, "result": "WA", "execution_time": "896 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A218B43BA0979", "submission_order": 3, "result": "AC", "execution_time": "1198 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n        # qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # qc.draw()\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A227D08D4F1C6", "submission_order": 1, "result": "AC", "execution_time": "1128 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A23EA0DE88B3C", "submission_order": 1, "result": "AC", "execution_time": "1118 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A24054E20428C", "submission_order": 1, "result": "WA", "execution_time": "930 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A24054E20428C", "submission_order": 2, "result": "RE", "execution_time": "784 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h()\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A24054E20428C", "submission_order": 3, "result": "AC", "execution_time": "1000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A24DFB033030E", "submission_order": 1, "result": "RE", "execution_time": "1201 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.g(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A24DFB033030E", "submission_order": 2, "result": "AC", "execution_time": "1594 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A257C058A7034", "submission_order": 1, "result": "AC", "execution_time": "2001 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A26AEEFF3CCFE", "submission_order": 1, "result": "AC", "execution_time": "2704 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A274CF7F90AE9", "submission_order": 1, "result": "AC", "execution_time": "1752 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply Hadamard gate to each qubit\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A27D7D456E4B2", "submission_order": 1, "result": "RE", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A27D7D456E4B2", "submission_order": 2, "result": "AC", "execution_time": "1114 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A27E87954B31A", "submission_order": 1, "result": "AC", "execution_time": "1494 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2890778D37BC", "submission_order": 1, "result": "RE", "execution_time": "1838 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2890778D37BC", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for q in range(n):\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2890778D37BC", "submission_order": 3, "result": "AC", "execution_time": "2043 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for q in range(n):\n        qc.h(q)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2A0DE6953FC9", "submission_order": 1, "result": "AC", "execution_time": "1018 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h([i])\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2A39923B28D3", "submission_order": 1, "result": "AC", "execution_time": "1005 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2A829EF7849A", "submission_order": 1, "result": "RE", "execution_time": "913 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2A829EF7849A", "submission_order": 2, "result": "AC", "execution_time": "1504 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2B961156FF41", "submission_order": 1, "result": "AC", "execution_time": "1123 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2C9A6CAC76FE", "submission_order": 1, "result": "AC", "execution_time": "2143 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2CE475A469F5", "submission_order": 1, "result": "AC", "execution_time": "1015 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2D38564A2D68", "submission_order": 1, "result": "WA", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2D38564A2D68", "submission_order": 2, "result": "AC", "execution_time": "994 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2DEBE1C9EC41", "submission_order": 1, "result": "AC", "execution_time": "1163 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2EC0F881B777", "submission_order": 1, "result": "AC", "execution_time": "1049 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2F3F02F38898", "submission_order": 1, "result": "AC", "execution_time": "1057 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2F7D242F2F4D", "submission_order": 1, "result": "AC", "execution_time": "1583 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A2FAF993B3F29", "submission_order": 1, "result": "AC", "execution_time": "1754 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3084441EF5A0", "submission_order": 1, "result": "AC", "execution_time": "1696 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A31460B41230D", "submission_order": 1, "result": "AC", "execution_time": "1081 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A31C8C1F44F7A", "submission_order": 1, "result": "AC", "execution_time": "2607 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A32475C5F98CB", "submission_order": 1, "result": "RE", "execution_time": "887 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(2**n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A32475C5F98CB", "submission_order": 2, "result": "AC", "execution_time": "1472 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A33150280F229", "submission_order": 1, "result": "RE", "execution_time": "1610 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A33150280F229", "submission_order": 2, "result": "RE", "execution_time": "1383 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A33150280F229", "submission_order": 3, "result": "AC", "execution_time": "2416 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A33DE3E3918CF", "submission_order": 1, "result": "AC", "execution_time": "1487 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A348C68437591", "submission_order": 1, "result": "AC", "execution_time": "991 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.append(\n            HGate(),  # New HGate instruction\n            [qubit]       # Apply to qubit 0\n        )\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A34CAFBFD885B", "submission_order": 1, "result": "AC", "execution_time": "1146 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A35BA6CFD3ABA", "submission_order": 1, "result": "AC", "execution_time": "2647 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3658546B3266", "submission_order": 1, "result": "AC", "execution_time": "1901 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3805DB0D1060", "submission_order": 1, "result": "AC", "execution_time": "1014 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n):\n    qc.h(i)\n  return qc\n'''"}
{"problem": "QPC001_A2", "user": "A383F47B79EBF", "submission_order": 1, "result": "WA", "execution_time": "1037 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for S in range(1<<n):\n        for i in range(n):\n            if (S >> i) & 1 == 1:\n                qc.x(i)\n            \n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A383F47B79EBF", "submission_order": 2, "result": "AC", "execution_time": "984 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3886DEDE653D", "submission_order": 1, "result": "AC", "execution_time": "1781 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A390BAAAA5A09", "submission_order": 1, "result": "AC", "execution_time": "1351 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3949028B3AA7", "submission_order": 1, "result": "AC", "execution_time": "1249 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A396A99A63FA9", "submission_order": 1, "result": "WA", "execution_time": "2312 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A396A99A63FA9", "submission_order": 2, "result": "AC", "execution_time": "2128 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3A406B3BC732", "submission_order": 1, "result": "AC", "execution_time": "1247 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3AE2E2879235", "submission_order": 1, "result": "RE", "execution_time": "3000 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.g(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3AE2E2879235", "submission_order": 2, "result": "RE", "execution_time": "1926 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    f\n\n    # Apply Hadamard to each qubit\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3AE2E2879235", "submission_order": 3, "result": "AC", "execution_time": "2120 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n\n    # Apply Hadamard to each qubit\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3C37AF9F2378", "submission_order": 1, "result": "RE", "execution_time": "826 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3C37AF9F2378", "submission_order": 2, "result": "AC", "execution_time": "1938 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3CA26879618F", "submission_order": 1, "result": "AC", "execution_time": "1937 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3D4EE989305C", "submission_order": 1, "result": "AC", "execution_time": "2571 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0, n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3D931BBA6EFD", "submission_order": 1, "result": "RE", "execution_time": "985 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3D931BBA6EFD", "submission_order": 2, "result": "RE", "execution_time": "1089 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3D931BBA6EFD", "submission_order": 3, "result": "AC", "execution_time": "970 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3EAB544379C0", "submission_order": 1, "result": "AC", "execution_time": "2835 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3EF083C639C9", "submission_order": 1, "result": "AC", "execution_time": "2625 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A3F8A9FC87F85", "submission_order": 1, "result": "AC", "execution_time": "2212 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A40B0EE20DECE", "submission_order": 1, "result": "WA", "execution_time": "1796 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A40B0EE20DECE", "submission_order": 2, "result": "AC", "execution_time": "1894 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A415F22A9D48E", "submission_order": 1, "result": "AC", "execution_time": "1352 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A41A969ABB621", "submission_order": 1, "result": "AC", "execution_time": "1193 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A41C86C6857E6", "submission_order": 1, "result": "AC", "execution_time": "1556 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A42F720EF183C", "submission_order": 1, "result": "AC", "execution_time": "1312 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A435F1B7280D2", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A435F993C650B", "submission_order": 1, "result": "AC", "execution_time": "1026 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A441C2E13DA03", "submission_order": 1, "result": "AC", "execution_time": "2352 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A443C95085358", "submission_order": 1, "result": "AC", "execution_time": "1685 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A44F8E02D931F", "submission_order": 1, "result": "AC", "execution_time": "1111 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4506C8069198", "submission_order": 1, "result": "AC", "execution_time": "1550 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int = 10) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\ndef debag(qc):\n    print(qc.draw(\"text\"))\ndef main():\n    debag(solve())\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC001_A2", "user": "A460F83ECD497", "submission_order": 1, "result": "WA", "execution_time": "1062 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A460F83ECD497", "submission_order": 2, "result": "AC", "execution_time": "1163 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4632CA1F9C98", "submission_order": 1, "result": "AC", "execution_time": "2046 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A46E3DE058ACB", "submission_order": 1, "result": "AC", "execution_time": "1757 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A47A35C740A1E", "submission_order": 1, "result": "RE", "execution_time": "2064 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.H(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A47A35C740A1E", "submission_order": 2, "result": "AC", "execution_time": "2023 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A487229974F1F", "submission_order": 1, "result": "RE", "execution_time": "952 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A487229974F1F", "submission_order": 2, "result": "RE", "execution_time": "797 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A487229974F1F", "submission_order": 3, "result": "AC", "execution_time": "996 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4A1439D2690C", "submission_order": 1, "result": "AC", "execution_time": "1622 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n\n\nprint(solve(1))\n'''"}
{"problem": "QPC001_A2", "user": "A4A696BB2AE3F", "submission_order": 1, "result": "AC", "execution_time": "1513 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4A80EEABF2D0", "submission_order": 1, "result": "AC", "execution_time": "1826 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4CD2668F0697", "submission_order": 1, "result": "AC", "execution_time": "2247 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4DC3A107BB39", "submission_order": 1, "result": "AC", "execution_time": "1185 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4DEDEC57BD31", "submission_order": 1, "result": "RE", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(4):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4DEDEC57BD31", "submission_order": 2, "result": "AC", "execution_time": "963 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4E2887C7F3C2", "submission_order": 1, "result": "AC", "execution_time": "1539 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4E87ED0499AD", "submission_order": 1, "result": "AC", "execution_time": "1064 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4EDED1D5A9F8", "submission_order": 1, "result": "AC", "execution_time": "1302 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A4F64064E6498", "submission_order": 1, "result": "AC", "execution_time": "2456 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A502091F84CF4", "submission_order": 1, "result": "AC", "execution_time": "1840 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.append(HGate(), [i])\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A50688E76C810", "submission_order": 1, "result": "RE", "execution_time": "1851 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(HGate(), list(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A50688E76C810", "submission_order": 2, "result": "AC", "execution_time": "2457 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A50E1E2A83602", "submission_order": 1, "result": "AC", "execution_time": "2286 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A51CA23DDBC8C", "submission_order": 1, "result": "AC", "execution_time": "1650 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5215680A03A5", "submission_order": 1, "result": "RE", "execution_time": "2188 ms", "memory": "82 MiB", "code": "'''python\n#import qiskit\nfrom qiskit import QuantumCircuit\n#from qiskit_aer import AerSimulator\n\ndef solve(n: int) -> QuantumCircuit:\n    circ = qiskit.QuantumCircuit(n)\n    for i in range(n):\n        circ.h(i)\n    #circ.measure_all()\n    # Construct an ideal simulator\n    #aersim = AerSimulator()\n\n    # Perform an ideal simulation\n    #result_ideal = qiskit.execute(circ, aersim).result()\n    #counts_ideal = result_ideal.get_counts(0)\n    #print('Counts(ideal):', counts_ideal)\n    return circ\n'''"}
{"problem": "QPC001_A2", "user": "A5215680A03A5", "submission_order": 2, "result": "RE", "execution_time": "890 ms", "memory": "79 MiB", "code": "'''python\n#import qiskit\nfrom qiskit import QuantumCircuit\n#from qiskit_aer import AerSimulator\n\ndef solve(n: int) -> QuantumCircuit:\n    circ = qiskit.QuantumCircuit(n)\n    for i in range(n):\n        circ.h(i)\n    circ.measure_all()\n    # Construct an ideal simulator\n    #aersim = AerSimulator()\n\n    # Perform an ideal simulation\n    #result_ideal = qiskit.execute(circ, aersim).result()\n    #counts_ideal = result_ideal.get_counts(0)\n    #print('Counts(ideal):', counts_ideal)\n    return circ\n'''"}
{"problem": "QPC001_A2", "user": "A5215680A03A5", "submission_order": 3, "result": "AC", "execution_time": "1525 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A52883A365761", "submission_order": 1, "result": "AC", "execution_time": "1650 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A529CC212038D", "submission_order": 1, "result": "WA", "execution_time": "920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A529CC212038D", "submission_order": 2, "result": "AC", "execution_time": "1129 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for t in range(n):\n        qc.h(t)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A53215A0ED100", "submission_order": 1, "result": "AC", "execution_time": "1715 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A53A5D10F6186", "submission_order": 1, "result": "AC", "execution_time": "1351 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A547611FE416B", "submission_order": 1, "result": "AC", "execution_time": "1554 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A54F4CFC8CCBB", "submission_order": 1, "result": "AC", "execution_time": "1047 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 1, "result": "RE", "execution_time": "789 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ccx(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 2, "result": "RE", "execution_time": "901 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 3, "result": "RE", "execution_time": "801 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 4, "result": "RE", "execution_time": "839 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(qc.h(n) - qc.z(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 5, "result": "RE", "execution_time": "826 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 6, "result": "RE", "execution_time": "824 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.x(i)\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 7, "result": "RE", "execution_time": "755 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.x(i)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 8, "result": "RE", "execution_time": "805 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.x(i)\n    qc.cz(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 9, "result": "RE", "execution_time": "814 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.x(i)\n        qc.cz(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 10, "result": "RE", "execution_time": "899 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(2 * n)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 11, "result": "RE", "execution_time": "818 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5587092D3111", "submission_order": 12, "result": "AC", "execution_time": "1394 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A57936D2BFAE4", "submission_order": 1, "result": "AC", "execution_time": "1115 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A57A79AC9EB23", "submission_order": 1, "result": "AC", "execution_time": "2168 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A57E463C29345", "submission_order": 1, "result": "AC", "execution_time": "2874 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A584AD4E7EB6E", "submission_order": 1, "result": "AC", "execution_time": "2081 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A58FA23AC42CD", "submission_order": 1, "result": "AC", "execution_time": "1168 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5905A8239D52", "submission_order": 1, "result": "WA", "execution_time": "979 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.z(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5905A8239D52", "submission_order": 2, "result": "AC", "execution_time": "1740 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A597991E05909", "submission_order": 1, "result": "RE", "execution_time": "772 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A597991E05909", "submission_order": 2, "result": "AC", "execution_time": "933 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A59ACE41AB2F4", "submission_order": 1, "result": "AC", "execution_time": "1934 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5A3574378636", "submission_order": 1, "result": "AC", "execution_time": "1101 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5A98D0A99224", "submission_order": 1, "result": "AC", "execution_time": "1629 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5B6E48E9038A", "submission_order": 1, "result": "RE", "execution_time": "1830 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    n = int(input())\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5B6E48E9038A", "submission_order": 2, "result": "RE", "execution_time": "1747 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    n = int(input())\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5B6E48E9038A", "submission_order": 3, "result": "AC", "execution_time": "2190 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5BC8CE3590C9", "submission_order": 1, "result": "AC", "execution_time": "1886 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5BFF77230D3C", "submission_order": 1, "result": "AC", "execution_time": "1076 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5DB047079550", "submission_order": 1, "result": "AC", "execution_time": "1819 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5DE72B3A0220", "submission_order": 1, "result": "RE", "execution_time": "828 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5DE72B3A0220", "submission_order": 2, "result": "AC", "execution_time": "1453 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5E145B09B570", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A5F667FA2DA55", "submission_order": 1, "result": "AC", "execution_time": "2817 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A609F1EC2BFFF", "submission_order": 1, "result": "AC", "execution_time": "2572 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A60A925DEF4C1", "submission_order": 1, "result": "AC", "execution_time": "1824 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A61337582BE38", "submission_order": 1, "result": "AC", "execution_time": "1021 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to each qubit\n    for qubit in range(n):\n        qc.h(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A613C8FE04864", "submission_order": 1, "result": "AC", "execution_time": "1701 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(0, n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A61466F3BE49F", "submission_order": 1, "result": "WA", "execution_time": "1381 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A61466F3BE49F", "submission_order": 2, "result": "AC", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A61DD237FB9D6", "submission_order": 1, "result": "AC", "execution_time": "1878 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A6261B3C9D405", "submission_order": 1, "result": "AC", "execution_time": "1051 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A64A71CE6D3EC", "submission_order": 1, "result": "RE", "execution_time": "801 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.add_H_gate(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A64A71CE6D3EC", "submission_order": 2, "result": "RE", "execution_time": "805 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A64A71CE6D3EC", "submission_order": 3, "result": "RE", "execution_time": "766 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n\n        qc.h(range(i))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A64A71CE6D3EC", "submission_order": 4, "result": "RE", "execution_time": "853 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n\n        qc.h(range(i))\n    qc=numpy.sqrt(n)*qc\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A64A71CE6D3EC", "submission_order": 5, "result": "RE", "execution_time": "848 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n\n        qc.h(range(i))/numpysqrt(2)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A64A71CE6D3EC", "submission_order": 6, "result": "RE", "execution_time": "835 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A64A71CE6D3EC", "submission_order": 7, "result": "RE", "execution_time": "873 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n\n        qc.h(range(i))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A64A71CE6D3EC", "submission_order": 8, "result": "AC", "execution_time": "1456 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A657E88B8C882", "submission_order": 1, "result": "RE", "execution_time": "1856 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n) \n    # for i in range(n):\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A657E88B8C882", "submission_order": 2, "result": "AC", "execution_time": "2175 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n)) \n    # for i in range(n):\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A67591923A419", "submission_order": 1, "result": "AC", "execution_time": "1329 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A684793A12680", "submission_order": 1, "result": "AC", "execution_time": "997 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A6D0DF8816CB4", "submission_order": 1, "result": "AC", "execution_time": "1637 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for ii in range(n): qc.h(ii)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A6D9ED1FA8A31", "submission_order": 1, "result": "RE", "execution_time": "1199 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A6D9ED1FA8A31", "submission_order": 2, "result": "AC", "execution_time": "1592 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A6E38F1C4455B", "submission_order": 1, "result": "AC", "execution_time": "1010 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A6E417122E0BC", "submission_order": 1, "result": "AC", "execution_time": "1594 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A6F670A4B23EE", "submission_order": 1, "result": "AC", "execution_time": "1955 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(0,n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7162E2EF06DB", "submission_order": 1, "result": "RE", "execution_time": "1780 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h[i]\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7162E2EF06DB", "submission_order": 2, "result": "AC", "execution_time": "1799 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A73F818C471A2", "submission_order": 1, "result": "AC", "execution_time": "1041 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A744F600C0B7A", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A749478B6EA80", "submission_order": 1, "result": "AC", "execution_time": "2062 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A74C68741ED19", "submission_order": 1, "result": "AC", "execution_time": "903 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A74CEA2B833E2", "submission_order": 1, "result": "AC", "execution_time": "980 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A75452A262062", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A75452A262062", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n-1))\n\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A75452A262062", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A75452A262062", "submission_order": 4, "result": "AC", "execution_time": "1532 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7565F237550C", "submission_order": 1, "result": "AC", "execution_time": "2112 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A76D0B3EBEEF3", "submission_order": 1, "result": "AC", "execution_time": "2128 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A79C7E15E94EB", "submission_order": 1, "result": "AC", "execution_time": "2052 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7B13CE5ABC41", "submission_order": 1, "result": "AC", "execution_time": "1479 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7B2CC4790CFF", "submission_order": 1, "result": "RE", "execution_time": "791 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.HGate(range((n)))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7B2CC4790CFF", "submission_order": 2, "result": "RE", "execution_time": "753 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.HGate(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7B2CC4790CFF", "submission_order": 3, "result": "RE", "execution_time": "768 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(qc.HGate(range(n)))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7B2CC4790CFF", "submission_order": 4, "result": "RE", "execution_time": "802 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0,2**n) :\n        qc.append(HGate(),i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7BE8155CDC4A", "submission_order": 1, "result": "RE", "execution_time": "817 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in rqange(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7BE8155CDC4A", "submission_order": 2, "result": "AC", "execution_time": "1039 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7C652C40DF7A", "submission_order": 1, "result": "AC", "execution_time": "1665 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7E5D6810D0C8", "submission_order": 1, "result": "AC", "execution_time": "1125 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A7F15D8D6F72A", "submission_order": 1, "result": "AC", "execution_time": "1544 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A801128B80E4C", "submission_order": 1, "result": "AC", "execution_time": "1622 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A80A44E7691DA", "submission_order": 1, "result": "AC", "execution_time": "1416 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A81454DA587DE", "submission_order": 1, "result": "AC", "execution_time": "1532 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8150DC0CDF35", "submission_order": 1, "result": "AC", "execution_time": "1329 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A826567502280", "submission_order": 1, "result": "AC", "execution_time": "1489 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A83BACA120A34", "submission_order": 1, "result": "AC", "execution_time": "1587 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A85A30C899ECF", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in range(n)\n        qc.h(_)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A85A30C899ECF", "submission_order": 2, "result": "AC", "execution_time": "1758 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in range(n):\n        qc.h(_)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A85AD6455123D", "submission_order": 1, "result": "AC", "execution_time": "1272 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A863364310054", "submission_order": 1, "result": "AC", "execution_time": "1183 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A86BE01D9489B", "submission_order": 1, "result": "AC", "execution_time": "2085 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A86D83129374C", "submission_order": 1, "result": "AC", "execution_time": "2173 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A87FCBB9411FF", "submission_order": 1, "result": "AC", "execution_time": "1901 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A88A5A97B40B0", "submission_order": 1, "result": "AC", "execution_time": "1239 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A88AAE9483D3C", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A896EEBD19186", "submission_order": 1, "result": "AC", "execution_time": "975 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i) \n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A89BC4DB0F8BA", "submission_order": 1, "result": "AC", "execution_time": "1988 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8A25FDD68175", "submission_order": 1, "result": "AC", "execution_time": "939 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8A813CE0940A", "submission_order": 1, "result": "AC", "execution_time": "1619 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8B15F07B7115", "submission_order": 1, "result": "AC", "execution_time": "1212 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8C42D8AF9892", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8C42D8AF9892", "submission_order": 2, "result": "AC", "execution_time": "1507 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8CC24D7A7C9A", "submission_order": 1, "result": "AC", "execution_time": "1267 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8E3EB19CB281", "submission_order": 1, "result": "AC", "execution_time": "2226 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8E519DB324B5", "submission_order": 1, "result": "AC", "execution_time": "1979 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8E7CCFD5FE89", "submission_order": 1, "result": "AC", "execution_time": "1032 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8E9066290FBA", "submission_order": 1, "result": "AC", "execution_time": "2335 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8EEC5EE584FA", "submission_order": 1, "result": "AC", "execution_time": "1926 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8EFDE77BF2C8", "submission_order": 1, "result": "AC", "execution_time": "1541 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8F6180B1228E", "submission_order": 1, "result": "AC", "execution_time": "1371 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8F7B3A69FB1C", "submission_order": 1, "result": "AC", "execution_time": "1604 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A8FF1450AD555", "submission_order": 1, "result": "AC", "execution_time": "1743 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A90D580E396D3", "submission_order": 1, "result": "AC", "execution_time": "1374 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9136CE690C2B", "submission_order": 1, "result": "AC", "execution_time": "1772 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)  # Apply Hadamard gate to each qubit\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A914A6D771A65", "submission_order": 1, "result": "AC", "execution_time": "2221 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A91FB743297E3", "submission_order": 1, "result": "AC", "execution_time": "1592 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A929822388D94", "submission_order": 1, "result": "AC", "execution_time": "1284 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A931E54659EFA", "submission_order": 1, "result": "AC", "execution_time": "1432 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A93FBE9110D95", "submission_order": 1, "result": "AC", "execution_time": "1120 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A941A5972B54D", "submission_order": 1, "result": "AC", "execution_time": "1545 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n): qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A960D1FE2D6D1", "submission_order": 1, "result": "AC", "execution_time": "1818 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(0, n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A977DC37D2E4B", "submission_order": 1, "result": "AC", "execution_time": "1079 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A977E3D29CC07", "submission_order": 1, "result": "AC", "execution_time": "1072 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A97C0A9E0BD6B", "submission_order": 1, "result": "AC", "execution_time": "1580 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A981C106C4C1D", "submission_order": 1, "result": "AC", "execution_time": "955 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # アダマールゲートを各量子ビットに適用\n    for qubit in range(n):\n        qc.h(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A98558C256594", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for(i=0;i<n;i++){\n        qc.h(i)\n    }\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A98558C256594", "submission_order": 2, "result": "AC", "execution_time": "1688 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9898DF97D2E6", "submission_order": 1, "result": "RE", "execution_time": "778 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_uniform_superposition(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # すべての量子ビットにアダマールゲートを適用\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9898DF97D2E6", "submission_order": 2, "result": "RE", "execution_time": "806 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_uniform_superposition(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # すべての量子ビットにアダマールゲートを適用\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A991A17BCABCC", "submission_order": 1, "result": "AC", "execution_time": "1457 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A991E03D52F3C", "submission_order": 1, "result": "RE", "execution_time": "892 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A991E03D52F3C", "submission_order": 2, "result": "RE", "execution_time": "833 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n);\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A991E03D52F3C", "submission_order": 3, "result": "AC", "execution_time": "1992 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A99C275143C88", "submission_order": 1, "result": "AC", "execution_time": "1415 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A99EB0FE52DCA", "submission_order": 1, "result": "WA", "execution_time": "981 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A99EB0FE52DCA", "submission_order": 2, "result": "AC", "execution_time": "1149 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9A11B5919B25", "submission_order": 1, "result": "WA", "execution_time": "1132 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9A11B5919B25", "submission_order": 2, "result": "RE", "execution_time": "975 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.cx(0, range(1, n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9A11B5919B25", "submission_order": 3, "result": "WA", "execution_time": "981 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9A11B5919B25", "submission_order": 4, "result": "RE", "execution_time": "1071 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.cx(0, range(1, n))\n    # for i in range(1, n):\n    #     qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9A11B5919B25", "submission_order": 5, "result": "RE", "execution_time": "954 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    if n >= 1:\n        qc.cx(0, range(1, n))\n    # for i in range(1, n):\n    #     qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9A11B5919B25", "submission_order": 6, "result": "AC", "execution_time": "1146 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(0, n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9A677B0E45C4", "submission_order": 1, "result": "AC", "execution_time": "2451 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9AD5CC57E335", "submission_order": 1, "result": "AC", "execution_time": "2342 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9CDA8B54796A", "submission_order": 1, "result": "AC", "execution_time": "1003 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9D5850BD842D", "submission_order": 1, "result": "AC", "execution_time": "1660 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9D74E18E8CBB", "submission_order": 1, "result": "AC", "execution_time": "993 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9ECEF9B3A146", "submission_order": 1, "result": "AC", "execution_time": "2056 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9FD4D6F149E9", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i=0\n    for i in range(n)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "A9FD4D6F149E9", "submission_order": 2, "result": "AC", "execution_time": "1630 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i=0\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA0D05A0028E8", "submission_order": 1, "result": "AC", "execution_time": "1182 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA0D6E67606A0", "submission_order": 1, "result": "AC", "execution_time": "2769 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA136767B3109", "submission_order": 1, "result": "AC", "execution_time": "2051 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA2BB6C0CB122", "submission_order": 1, "result": "AC", "execution_time": "1002 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA2CDBBFD85ED", "submission_order": 1, "result": "AC", "execution_time": "1432 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA30421FBE97B", "submission_order": 1, "result": "AC", "execution_time": "1346 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA380AE26553B", "submission_order": 1, "result": "AC", "execution_time": "1848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA4AEFCE24CD4", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA52309C675F0", "submission_order": 1, "result": "AC", "execution_time": "1573 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA528534C5623", "submission_order": 1, "result": "AC", "execution_time": "1121 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA9367E7A83E3", "submission_order": 1, "result": "AC", "execution_time": "1657 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AA95A3BDE0F08", "submission_order": 1, "result": "AC", "execution_time": "1497 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAAD123BADA57", "submission_order": 1, "result": "AC", "execution_time": "1064 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# from qiskit import (BasicAer,execute)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n, n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AABAD928835FC", "submission_order": 1, "result": "AC", "execution_time": "1041 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAD62F5C8835D", "submission_order": 1, "result": "AC", "execution_time": "2313 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AADFE1B4598F2", "submission_order": 1, "result": "AC", "execution_time": "1197 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAE3316987D48", "submission_order": 1, "result": "AC", "execution_time": "1010 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAE601E69182E", "submission_order": 1, "result": "RE", "execution_time": "1454 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAE601E69182E", "submission_order": 2, "result": "AC", "execution_time": "1700 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAE69363C585C", "submission_order": 1, "result": "AC", "execution_time": "1386 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAEA32A6449F1", "submission_order": 1, "result": "RE", "execution_time": "2219 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAEA32A6449F1", "submission_order": 2, "result": "RE", "execution_time": "2047 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAEA32A6449F1", "submission_order": 3, "result": "RE", "execution_time": "2117 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAEA32A6449F1", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for k range in(n)\n    qc.h(k)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAEA32A6449F1", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for k range(n):\n    qc.h(k)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAEA32A6449F1", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for k in range(n):\n    qc.h(k)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAEA32A6449F1", "submission_order": 7, "result": "AC", "execution_time": "2079 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n     qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAEFA97E1AA7E", "submission_order": 1, "result": "AC", "execution_time": "1061 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AAF843AB50362", "submission_order": 1, "result": "AC", "execution_time": "2366 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB0F399F291C2", "submission_order": 1, "result": "AC", "execution_time": "1878 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB1AE690A3585", "submission_order": 1, "result": "AC", "execution_time": "2384 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # 各量子ビットにHゲートを適用\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB298A7E0C76D", "submission_order": 1, "result": "AC", "execution_time": "1821 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB44C6FA14CAF", "submission_order": 1, "result": "RE", "execution_time": "1594 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(HGate(), [0])\n    qc.append(HGate(), [1])\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB44C6FA14CAF", "submission_order": 2, "result": "AC", "execution_time": "1498 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.append(HGate(), [i])\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB468FFC98B75", "submission_order": 1, "result": "AC", "execution_time": "1601 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB64F7FE7B26B", "submission_order": 1, "result": "AC", "execution_time": "1185 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB65CBA8580A7", "submission_order": 1, "result": "AC", "execution_time": "1827 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB68C05B6DC7A", "submission_order": 1, "result": "WA", "execution_time": "1685 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB68C05B6DC7A", "submission_order": 2, "result": "RE", "execution_time": "1528 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.g(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB68C05B6DC7A", "submission_order": 3, "result": "AC", "execution_time": "1678 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB695853BB4E2", "submission_order": 1, "result": "AC", "execution_time": "948 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB6F3795ECBAE", "submission_order": 1, "result": "AC", "execution_time": "1559 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB7A87FD46648", "submission_order": 1, "result": "AC", "execution_time": "1929 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB7E3E3601C38", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB866962DCBEB", "submission_order": 1, "result": "AC", "execution_time": "1713 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB87DCD09D216", "submission_order": 1, "result": "AC", "execution_time": "1286 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB92A171FCBDF", "submission_order": 1, "result": "RE", "execution_time": "1594 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB92A171FCBDF", "submission_order": 2, "result": "AC", "execution_time": "1753 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB995F288132E", "submission_order": 1, "result": "RE", "execution_time": "808 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.unitary(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB995F288132E", "submission_order": 2, "result": "AC", "execution_time": "1485 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB9E998BB7BEC", "submission_order": 1, "result": "AC", "execution_time": "2707 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AB9EB15AEC660", "submission_order": 1, "result": "AC", "execution_time": "1019 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABA759B357D43", "submission_order": 1, "result": "AC", "execution_time": "2329 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABABE7ACCC554", "submission_order": 1, "result": "AC", "execution_time": "1955 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABB09565EC7D7", "submission_order": 1, "result": "AC", "execution_time": "1383 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABC0F629CEF2A", "submission_order": 1, "result": "AC", "execution_time": "1768 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABC7EB4CF5474", "submission_order": 1, "result": "AC", "execution_time": "1493 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABCA51D5F3750", "submission_order": 1, "result": "AC", "execution_time": "1064 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABD576B6FB589", "submission_order": 1, "result": "RE", "execution_time": "915 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABD576B6FB589", "submission_order": 2, "result": "AC", "execution_time": "1002 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(0, n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABD63E5B89392", "submission_order": 1, "result": "AC", "execution_time": "1314 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABE134A8F216F", "submission_order": 1, "result": "AC", "execution_time": "2391 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    for l in range(n):\n        qc.append(HGate(),[l],)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABE5196CF197B", "submission_order": 1, "result": "WA", "execution_time": "1817 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABE5196CF197B", "submission_order": 2, "result": "AC", "execution_time": "2077 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABF371CAA6E0F", "submission_order": 1, "result": "AC", "execution_time": "2179 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ABFAC44FCC2AC", "submission_order": 1, "result": "AC", "execution_time": "2299 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC0CC6A4B5719", "submission_order": 1, "result": "RE", "execution_time": "1235 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n-1))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC0CC6A4B5719", "submission_order": 2, "result": "AC", "execution_time": "1433 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC11AE21E6BE4", "submission_order": 1, "result": "AC", "execution_time": "2410 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC20385EC447B", "submission_order": 1, "result": "AC", "execution_time": "1732 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC268C9168BE3", "submission_order": 1, "result": "AC", "execution_time": "1425 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC343E945E600", "submission_order": 1, "result": "AC", "execution_time": "1302 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC37503EDB207", "submission_order": 1, "result": "AC", "execution_time": "1083 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC38114A62E80", "submission_order": 1, "result": "AC", "execution_time": "1620 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC3EC0BE73DDD", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC43CA1AC66D0", "submission_order": 1, "result": "AC", "execution_time": "1067 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC449D56C6BF9", "submission_order": 1, "result": "AC", "execution_time": "1312 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC49D2066A833", "submission_order": 1, "result": "RE", "execution_time": "2348 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(\n        HGate(),\n        range(n),\n    )\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC49D2066A833", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.append(\n        HGate(),\n        [i],\n      )\n    )\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC49D2066A833", "submission_order": 3, "result": "AC", "execution_time": "2538 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.append(\n        HGate(),\n        [i],\n      )\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC4AE4D554BFD", "submission_order": 1, "result": "AC", "execution_time": "991 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC4CA26D4D94D", "submission_order": 1, "result": "AC", "execution_time": "1447 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC735A558C4D3", "submission_order": 1, "result": "AC", "execution_time": "2192 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC77599114A7F", "submission_order": 1, "result": "WA", "execution_time": "1824 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC77599114A7F", "submission_order": 2, "result": "AC", "execution_time": "2260 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC7B661217CBF", "submission_order": 1, "result": "AC", "execution_time": "1700 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AC9CD23D5F802", "submission_order": 1, "result": "AC", "execution_time": "969 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACA1E36BE5798", "submission_order": 1, "result": "RE", "execution_time": "1569 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.cnot(i, i+1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACA1E36BE5798", "submission_order": 2, "result": "RE", "execution_time": "2016 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.cnot(i, i+1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACA1E36BE5798", "submission_order": 3, "result": "RE", "execution_time": "2036 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.cnot((i+1), i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACA1E36BE5798", "submission_order": 4, "result": "RE", "execution_time": "1496 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n-1):\n        qc.cnot(i, i+1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACA1E36BE5798", "submission_order": 5, "result": "AC", "execution_time": "1837 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACC077C460FB7", "submission_order": 1, "result": "AC", "execution_time": "2268 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACE67B173F9C5", "submission_order": 1, "result": "AC", "execution_time": "2286 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACE933956E360", "submission_order": 1, "result": "AC", "execution_time": "2418 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACEA5A8D95C2C", "submission_order": 1, "result": "AC", "execution_time": "1212 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACEAD6590977B", "submission_order": 1, "result": "AC", "execution_time": "973 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ACF1E05FAE91A", "submission_order": 1, "result": "AC", "execution_time": "1952 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD069921A4D0A", "submission_order": 1, "result": "AC", "execution_time": "2493 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD08ACE3ED074", "submission_order": 1, "result": "AC", "execution_time": "2434 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD0D7D10E4904", "submission_order": 1, "result": "RE", "execution_time": "1993 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD0D7D10E4904", "submission_order": 2, "result": "AC", "execution_time": "1720 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD174402BAB3D", "submission_order": 1, "result": "AC", "execution_time": "1070 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD1993BE37F31", "submission_order": 1, "result": "WA", "execution_time": "1023 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD1993BE37F31", "submission_order": 2, "result": "AC", "execution_time": "2349 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD1BD7CD9D2F1", "submission_order": 1, "result": "AC", "execution_time": "2882 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD23C9DA2AA67", "submission_order": 1, "result": "AC", "execution_time": "2055 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD2B07D273E44", "submission_order": 1, "result": "AC", "execution_time": "1688 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD4A6A01DE533", "submission_order": 1, "result": "AC", "execution_time": "982 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD522919129B5", "submission_order": 1, "result": "AC", "execution_time": "1156 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD5CA0787B220", "submission_order": 1, "result": "AC", "execution_time": "933 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD63B09E0B14D", "submission_order": 1, "result": "AC", "execution_time": "1067 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(list(range(n)))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD6DE0F1A7CED", "submission_order": 1, "result": "RE", "execution_time": "1289 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD6DE0F1A7CED", "submission_order": 2, "result": "AC", "execution_time": "1188 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD6E4B0C85C95", "submission_order": 1, "result": "AC", "execution_time": "1543 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD7CB97DD69CD", "submission_order": 1, "result": "AC", "execution_time": "1084 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD878C2BE9108", "submission_order": 1, "result": "RE", "execution_time": "976 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n      qc.h(i) \n  return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD878C2BE9108", "submission_order": 2, "result": "AC", "execution_time": "1141 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n):\n    qc.h(i) \n  return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD95108C43A46", "submission_order": 1, "result": "AC", "execution_time": "2230 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AD9C7597D50A4", "submission_order": 1, "result": "AC", "execution_time": "1271 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADBC3BFE17E21", "submission_order": 1, "result": "AC", "execution_time": "1462 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADCB09F7E83E3", "submission_order": 1, "result": "WA", "execution_time": "842 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADCB09F7E83E3", "submission_order": 2, "result": "AC", "execution_time": "1185 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADCC2FA913D8D", "submission_order": 1, "result": "AC", "execution_time": "1685 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADD2E09D8EE2A", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n        for i range(n)\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADD2E09D8EE2A", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADD2E09D8EE2A", "submission_order": 3, "result": "AC", "execution_time": "1999 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADDE31C09447D", "submission_order": 1, "result": "RE", "execution_time": "804 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n    qc.h(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADDE31C09447D", "submission_order": 2, "result": "AC", "execution_time": "1150 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADE09311DE63F", "submission_order": 1, "result": "AC", "execution_time": "1554 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADEB9D1201C25", "submission_order": 1, "result": "AC", "execution_time": "1110 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "ADF335EDFC96F", "submission_order": 1, "result": "AC", "execution_time": "2067 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE0305D1D38DF", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE0305D1D38DF", "submission_order": 2, "result": "AC", "execution_time": "1706 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE0893E588339", "submission_order": 1, "result": "AC", "execution_time": "1524 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE1BA48AC8C99", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, execute\nfrom qiskit.visualization import plot_state_qsphere\nimport matplotlib.pyplot as plt\n\n# solve関数の定義\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE1BA48AC8C99", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, execute\n# from qiskit.visualization import plot_state_qsphere\n# import matplotlib.pyplot as plt\n\n# solve関数の定義\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE1BA48AC8C99", "submission_order": 3, "result": "AC", "execution_time": "977 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_state_qsphere\n# import matplotlib.pyplot as plt\n\n# solve関数の定義\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE2C935D26355", "submission_order": 1, "result": "AC", "execution_time": "1002 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE2ED94DD3C5E", "submission_order": 1, "result": "AC", "execution_time": "1766 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE39E2A3F736B", "submission_order": 1, "result": "AC", "execution_time": "1095 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE48C011E3DE1", "submission_order": 1, "result": "AC", "execution_time": "2411 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE4CA40DB4A6A", "submission_order": 1, "result": "AC", "execution_time": "2296 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to each qubit\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE4D7A2D7FB08", "submission_order": 1, "result": "AC", "execution_time": "1775 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h((range(n)))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE4F106B8A6FC", "submission_order": 1, "result": "AC", "execution_time": "1720 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE6A6CCE09082", "submission_order": 1, "result": "AC", "execution_time": "969 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE6BB3AA15287", "submission_order": 1, "result": "RE", "execution_time": "1385 ms", "memory": "140 MiB", "code": "'''python\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE6BB3AA15287", "submission_order": 2, "result": "AC", "execution_time": "1512 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE72001F834A1", "submission_order": 1, "result": "RE", "execution_time": "823 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n   for qubit in range(n):\n        qc.h(qubit)  # 各量子ビットにHゲートを適用\n    return qc\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE72001F834A1", "submission_order": 2, "result": "RE", "execution_time": "1049 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n   for qubit in range(n):\n        qc.h(qubit)  # 各量子ビットにHゲートを適用\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE7C12CED84C1", "submission_order": 1, "result": "AC", "execution_time": "1586 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(list(range(n)))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE9342A99CC7E", "submission_order": 1, "result": "AC", "execution_time": "1678 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AE9ECAB455F80", "submission_order": 1, "result": "AC", "execution_time": "1181 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEAA163A280BB", "submission_order": 1, "result": "AC", "execution_time": "2120 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEAB0BED36700", "submission_order": 1, "result": "AC", "execution_time": "1203 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEAB3AE0BFF99", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEB8FF5C744A4", "submission_order": 1, "result": "AC", "execution_time": "2206 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEC6328CE8281", "submission_order": 1, "result": "RE", "execution_time": "2696 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.g(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEC6328CE8281", "submission_order": 2, "result": "AC", "execution_time": "2845 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AED86ACB28EFA", "submission_order": 1, "result": "RE", "execution_time": "801 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.g(range(n))\n\n    qc.draw(\"mpl\")\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AED86ACB28EFA", "submission_order": 2, "result": "AC", "execution_time": "963 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEDEBDF4E7389", "submission_order": 1, "result": "AC", "execution_time": "1653 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEF8A455F8550", "submission_order": 1, "result": "AC", "execution_time": "1568 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AEFE2F4517008", "submission_order": 1, "result": "AC", "execution_time": "2435 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF084A542F347", "submission_order": 1, "result": "AC", "execution_time": "1110 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF109393B3658", "submission_order": 1, "result": "AC", "execution_time": "1619 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF126F963DF6B", "submission_order": 1, "result": "WA", "execution_time": "932 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF126F963DF6B", "submission_order": 2, "result": "AC", "execution_time": "1679 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF26F4AA42E4C", "submission_order": 1, "result": "AC", "execution_time": "2207 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF323AD776564", "submission_order": 1, "result": "AC", "execution_time": "2387 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF378FC4CA42F", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF378FC4CA42F", "submission_order": 2, "result": "AC", "execution_time": "2055 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF3A67AB47BB0", "submission_order": 1, "result": "AC", "execution_time": "1465 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF4E12E3D85CA", "submission_order": 1, "result": "WA", "execution_time": "925 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF4E12E3D85CA", "submission_order": 2, "result": "WA", "execution_time": "959 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF4E12E3D85CA", "submission_order": 3, "result": "AC", "execution_time": "1025 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF52745AE2D7B", "submission_order": 1, "result": "AC", "execution_time": "2371 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF5D4133F92D8", "submission_order": 1, "result": "AC", "execution_time": "2212 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF713ECA20182", "submission_order": 1, "result": "AC", "execution_time": "1480 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF776402A1A6F", "submission_order": 1, "result": "WA", "execution_time": "1031 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF776402A1A6F", "submission_order": 2, "result": "AC", "execution_time": "1158 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF7DEC7BD0790", "submission_order": 1, "result": "AC", "execution_time": "1044 ms", "memory": "90 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n \n    return qc\n# %%\n'''"}
{"problem": "QPC001_A2", "user": "AF8A0533D5833", "submission_order": 1, "result": "AC", "execution_time": "1123 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AF9E9C0C87EF3", "submission_order": 1, "result": "AC", "execution_time": "1486 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFB25EEB8BDA3", "submission_order": 1, "result": "AC", "execution_time": "2112 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFB36D837E82D", "submission_order": 1, "result": "AC", "execution_time": "2203 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFB4CED9DBF1D", "submission_order": 1, "result": "AC", "execution_time": "1786 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFC58E0F022C2", "submission_order": 1, "result": "RE", "execution_time": "2248 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    for _ in range(n):\n        qc.h(_)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFC58E0F022C2", "submission_order": 2, "result": "AC", "execution_time": "2108 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in range(n):\n        qc.h(_)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFC71F8127E83", "submission_order": 1, "result": "AC", "execution_time": "2091 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFD16BA0EB336", "submission_order": 1, "result": "AC", "execution_time": "1600 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFD5FCF528B2C", "submission_order": 1, "result": "AC", "execution_time": "1054 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFDB4C21B7C64", "submission_order": 1, "result": "RE", "execution_time": "891 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,range(1,10))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFDB4C21B7C64", "submission_order": 2, "result": "AC", "execution_time": "1810 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(0,n))\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFE4DF8782C21", "submission_order": 1, "result": "AC", "execution_time": "1281 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A2", "user": "AFEB56B664B64", "submission_order": 1, "result": "AC", "execution_time": "2262 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)  # Hadamard gate\n\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(qc)\n'''"}
{"problem": "QPC001_A2", "user": "AFF09B060B747", "submission_order": 1, "result": "AC", "execution_time": "1611 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A010AECBCD9A7", "submission_order": 1, "result": "AC", "execution_time": "1632 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A010C10CE5716", "submission_order": 1, "result": "AC", "execution_time": "815 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A01B7C0F397CC", "submission_order": 1, "result": "AC", "execution_time": "811 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0248D7A8EADD", "submission_order": 1, "result": "RE", "execution_time": "1507 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qa.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0248D7A8EADD", "submission_order": 2, "result": "RE", "execution_time": "1568 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qa.cx([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0248D7A8EADD", "submission_order": 3, "result": "RE", "execution_time": "1404 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qa.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0248D7A8EADD", "submission_order": 4, "result": "AC", "execution_time": "1596 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A02506C091CA2", "submission_order": 1, "result": "AC", "execution_time": "1007 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A02CFA7F61DBA", "submission_order": 1, "result": "WA", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A02CFA7F61DBA", "submission_order": 2, "result": "AC", "execution_time": "805 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A03A37C2AA128", "submission_order": 1, "result": "AC", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A04209B8AE7F2", "submission_order": 1, "result": "RE", "execution_time": "775 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    with qc.if_test((0,1)):\n        qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A04209B8AE7F2", "submission_order": 2, "result": "AC", "execution_time": "826 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A048BEC40350F", "submission_order": 1, "result": "AC", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A04AAE19421ED", "submission_order": 1, "result": "AC", "execution_time": "901 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A05518678F771", "submission_order": 1, "result": "WA", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A05518678F771", "submission_order": 2, "result": "AC", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A05B68578EF5A", "submission_order": 1, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A05BB46448C35", "submission_order": 1, "result": "AC", "execution_time": "818 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A063431549968", "submission_order": 1, "result": "AC", "execution_time": "847 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A06A91FE0CA26", "submission_order": 1, "result": "AC", "execution_time": "1794 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A07BE0DFA8F62", "submission_order": 1, "result": "AC", "execution_time": "1529 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A092F342A51F3", "submission_order": 1, "result": "WA", "execution_time": "1365 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A092F342A51F3", "submission_order": 2, "result": "AC", "execution_time": "1356 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0A28E55FB298", "submission_order": 1, "result": "AC", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0A33555AEC2F", "submission_order": 1, "result": "AC", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0A82799D0F81", "submission_order": 1, "result": "WA", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0A82799D0F81", "submission_order": 2, "result": "AC", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0A9C265C6365", "submission_order": 1, "result": "WA", "execution_time": "804 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0A9C265C6365", "submission_order": 2, "result": "WA", "execution_time": "806 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0A9C265C6365", "submission_order": 3, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0A9C265C6365", "submission_order": 4, "result": "AC", "execution_time": "1494 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0B4B704D4E0F", "submission_order": 1, "result": "AC", "execution_time": "1436 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0B87D8CF0E7A", "submission_order": 1, "result": "AC", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0C64CCCF663F", "submission_order": 1, "result": "AC", "execution_time": "842 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0D1A2E28B206", "submission_order": 1, "result": "AC", "execution_time": "874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0D37ADED6E9E", "submission_order": 1, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:)\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0E025AF6F695", "submission_order": 1, "result": "AC", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0E9F0878BE70", "submission_order": 1, "result": "AC", "execution_time": "1619 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A0F25550CB172", "submission_order": 1, "result": "AC", "execution_time": "1380 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A103F033CDE88", "submission_order": 1, "result": "RE", "execution_time": "816 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cnot(qc.h[0],1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A103F033CDE88", "submission_order": 2, "result": "RE", "execution_time": "825 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n\n    # Write your code here:\n\n    qc = QuantumCircuit(2)\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc.h(x)\n    qc.cnot(x,y)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A103F033CDE88", "submission_order": 3, "result": "AC", "execution_time": "946 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n\n    # Write your code here:\n\n    qc = QuantumCircuit(2)\n    q = QuantumRegister(2,'q')\n    qc.h(q[0])\n    qc.cnot(q[0],q[1])\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A11C15F62EBB6", "submission_order": 1, "result": "WA", "execution_time": "1767 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A11C15F62EBB6", "submission_order": 2, "result": "AC", "execution_time": "1792 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A11E209CA2DBF", "submission_order": 1, "result": "WA", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A11E209CA2DBF", "submission_order": 2, "result": "AC", "execution_time": "1056 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1332DE1F43BC", "submission_order": 1, "result": "AC", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1362F7D81CA3", "submission_order": 1, "result": "AC", "execution_time": "1541 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A14969A45BC59", "submission_order": 1, "result": "AC", "execution_time": "902 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A152E523F400D", "submission_order": 1, "result": "RE", "execution_time": "738 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A152E523F400D", "submission_order": 2, "result": "AC", "execution_time": "845 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1582270AEC25", "submission_order": 1, "result": "AC", "execution_time": "1531 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1639B988B705", "submission_order": 1, "result": "AC", "execution_time": "1097 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A164A35FEA7BE", "submission_order": 1, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16538DCD9FFE", "submission_order": 1, "result": "AC", "execution_time": "1362 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 1, "result": "WA", "execution_time": "912 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 2, "result": "RE", "execution_time": "895 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 3, "result": "RE", "execution_time": "955 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0,2)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 4, "result": "WA", "execution_time": "926 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h([0,1])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 5, "result": "WA", "execution_time": "818 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx([0],[1])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 6, "result": "WA", "execution_time": "1103 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    for i in range(4):\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 7, "result": "WA", "execution_time": "1034 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 8, "result": "RE", "execution_time": "763 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16AFD5D15050", "submission_order": 9, "result": "AC", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A16C759C3D79B", "submission_order": 1, "result": "AC", "execution_time": "1709 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A172EB375ABB7", "submission_order": 1, "result": "AC", "execution_time": "821 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A17E56DD077DD", "submission_order": 1, "result": "AC", "execution_time": "1970 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A18D0E3A75111", "submission_order": 1, "result": "AC", "execution_time": "1597 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A190DD83FA49F", "submission_order": 1, "result": "AC", "execution_time": "879 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1995167B3505", "submission_order": 1, "result": "AC", "execution_time": "862 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1B14FACE1BB3", "submission_order": 1, "result": "AC", "execution_time": "1907 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    # Apply CNOT gate with control on the first qubit and target on the second qubit\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1B9488D7AD97", "submission_order": 1, "result": "WA", "execution_time": "1436 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1BDEEFB88C2C", "submission_order": 1, "result": "AC", "execution_time": "1106 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1CA7D9A4F394", "submission_order": 1, "result": "AC", "execution_time": "1766 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1D5D63B9088E", "submission_order": 1, "result": "AC", "execution_time": "812 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1DE0468E817B", "submission_order": 1, "result": "AC", "execution_time": "1711 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1DEC2B902A3F", "submission_order": 1, "result": "AC", "execution_time": "1509 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1DEE27E182D6", "submission_order": 1, "result": "AC", "execution_time": "1099 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1F2FF772F166", "submission_order": 1, "result": "AC", "execution_time": "970 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1F8DE618D09D", "submission_order": 1, "result": "WA", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A1F8DE618D09D", "submission_order": 2, "result": "AC", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2039D830DC14", "submission_order": 1, "result": "AC", "execution_time": "1096 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A205202404DCD", "submission_order": 1, "result": "AC", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2127F124C807", "submission_order": 1, "result": "WA", "execution_time": "1515 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2158C271BD4B", "submission_order": 1, "result": "AC", "execution_time": "1393 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A21F50DA084B5", "submission_order": 1, "result": "AC", "execution_time": "842 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A238A8BCB874C", "submission_order": 1, "result": "AC", "execution_time": "935 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A23AF655C4D3E", "submission_order": 1, "result": "WA", "execution_time": "1448 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A23AF655C4D3E", "submission_order": 2, "result": "AC", "execution_time": "1547 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A246B3E16DEAC", "submission_order": 1, "result": "AC", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A24BD12F6A07C", "submission_order": 1, "result": "AC", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# from qiskit import (BasicAer,execute)\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2, 2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A25F85FB2490C", "submission_order": 1, "result": "AC", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A262BA5628705", "submission_order": 1, "result": "RE", "execution_time": "1396 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(n))\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A262BA5628705", "submission_order": 2, "result": "RE", "execution_time": "1462 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A262BA5628705", "submission_order": 3, "result": "RE", "execution_time": "1405 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A262BA5628705", "submission_order": 4, "result": "RE", "execution_time": "1418 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A262BA5628705", "submission_order": 5, "result": "RE", "execution_time": "1469 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.T(range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A262BA5628705", "submission_order": 6, "result": "RE", "execution_time": "1404 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0.1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A262BA5628705", "submission_order": 7, "result": "AC", "execution_time": "1448 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2772A0D13CAF", "submission_order": 1, "result": "AC", "execution_time": "1626 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2798DF474668", "submission_order": 1, "result": "AC", "execution_time": "1485 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A282503E76CDE", "submission_order": 1, "result": "AC", "execution_time": "950 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A28FC6DC6A74C", "submission_order": 1, "result": "AC", "execution_time": "1253 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A296F9693F268", "submission_order": 1, "result": "AC", "execution_time": "1356 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2AB654BBC603", "submission_order": 1, "result": "AC", "execution_time": "1671 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2ABCC3B09434", "submission_order": 1, "result": "AC", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2B4A3D0B3CC3", "submission_order": 1, "result": "AC", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2BCE0CAC65B3", "submission_order": 1, "result": "AC", "execution_time": "965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2D18310E44B1", "submission_order": 1, "result": "WA", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2D18310E44B1", "submission_order": 2, "result": "WA", "execution_time": "1116 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2D18310E44B1", "submission_order": 3, "result": "AC", "execution_time": "862 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2DF1BCA558F7", "submission_order": 1, "result": "AC", "execution_time": "1867 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2E52AD7E7E98", "submission_order": 1, "result": "AC", "execution_time": "1254 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2ED34F1A24FE", "submission_order": 1, "result": "AC", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A2F25198260EE", "submission_order": 1, "result": "AC", "execution_time": "1768 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A31EF9C99A4A9", "submission_order": 1, "result": "AC", "execution_time": "965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3225041DE4BB", "submission_order": 1, "result": "AC", "execution_time": "1567 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A32DF8314B2F2", "submission_order": 1, "result": "WA", "execution_time": "889 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A32DF8314B2F2", "submission_order": 2, "result": "RE", "execution_time": "746 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A32DF8314B2F2", "submission_order": 3, "result": "AC", "execution_time": "874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A33182690773A", "submission_order": 1, "result": "WA", "execution_time": "1630 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.x(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A33B44B1DA842", "submission_order": 1, "result": "WA", "execution_time": "824 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A33B44B1DA842", "submission_order": 2, "result": "WA", "execution_time": "1162 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A33B44B1DA842", "submission_order": 3, "result": "AC", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A341BB38A1F8D", "submission_order": 1, "result": "AC", "execution_time": "1424 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A34233DD9141A", "submission_order": 1, "result": "RE", "execution_time": "793 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.measure([0,0],[1,1])\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A34233DD9141A", "submission_order": 2, "result": "RE", "execution_time": "913 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.measure([0,0],[1,1])\n    qc.draw('mpl')\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A34233DD9141A", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.initialize([1/np.sqrt(2), 3/np.sqrt(2)], 0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A34233DD9141A", "submission_order": 4, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2,2)\n    # Write your code here:\n    qc.measure(0, 0)\n    qc.measure(1, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A34233DD9141A", "submission_order": 5, "result": "RE", "execution_time": "742 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.measure(0,3)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A34233DD9141A", "submission_order": 6, "result": "RE", "execution_time": "1361 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.measure(0,3)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3482C65CCB1F", "submission_order": 1, "result": "AC", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A353FA2239299", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A36066D358B62", "submission_order": 1, "result": "AC", "execution_time": "1574 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A37380237B962", "submission_order": 1, "result": "AC", "execution_time": "842 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A37724AB7FC62", "submission_order": 1, "result": "AC", "execution_time": "915 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A37E926CE8535", "submission_order": 1, "result": "AC", "execution_time": "915 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A38638F57ADAE", "submission_order": 1, "result": "RE", "execution_time": "1856 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import  CXGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.append(\n        HGate(),\n        [0],\n    )\n    qc.append(\n        CXGate(),\n        [0,1]\n    )\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A38638F57ADAE", "submission_order": 2, "result": "AC", "execution_time": "2023 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3A4F4691E424", "submission_order": 1, "result": "AC", "execution_time": "1747 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3A541CDFC85E", "submission_order": 1, "result": "RE", "execution_time": "1519 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(1, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3A541CDFC85E", "submission_order": 2, "result": "AC", "execution_time": "1592 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3CF09A5A948B", "submission_order": 1, "result": "AC", "execution_time": "904 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3CFF3799BB23", "submission_order": 1, "result": "AC", "execution_time": "1566 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3DF8408345E6", "submission_order": 1, "result": "AC", "execution_time": "1929 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # 最初の量子ビットにアダマールゲートを適用\n    qc.h(0)\n    # CNOTゲートを適用 (最初の量子ビットを制御ビットとする)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3E22A16CA8C6", "submission_order": 1, "result": "RE", "execution_time": "737 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3E22A16CA8C6", "submission_order": 2, "result": "AC", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A3E315367F1C2", "submission_order": 1, "result": "AC", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A400497500C14", "submission_order": 1, "result": "AC", "execution_time": "1910 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4028075476F5", "submission_order": 1, "result": "WA", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # アダマールゲートを各量子ビットに適用\n    qc.h(0)\n    qc.h(1)\n    \n    # CNOTゲートを適用してエンタングル状態を生成\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4028075476F5", "submission_order": 2, "result": "WA", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # アダマールゲートを各量子ビットに適用\n    qc.h(0)\n    qc.h(1)\n    \n    # CNOTゲートを適用してエンタングル状態を生成\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4028075476F5", "submission_order": 3, "result": "WA", "execution_time": "1605 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply Hadamard gate to each qubit\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A402E1CF3B3A9", "submission_order": 1, "result": "AC", "execution_time": "818 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A40903B6FD63F", "submission_order": 1, "result": "AC", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A40B7DA948BF1", "submission_order": 1, "result": "AC", "execution_time": "1147 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A410A893F3EAF", "submission_order": 1, "result": "AC", "execution_time": "1634 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A412060F463D1", "submission_order": 1, "result": "AC", "execution_time": "999 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4242992313F5", "submission_order": 1, "result": "AC", "execution_time": "1598 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4251123E8B30", "submission_order": 1, "result": "AC", "execution_time": "913 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A43604720C8AC", "submission_order": 1, "result": "AC", "execution_time": "1403 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\ndef debag(qc):\n    print(qc.draw(\"text\"))\ndef main():\n    debag(solve())\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC001_A3", "user": "A43E46811CEF1", "submission_order": 1, "result": "AC", "execution_time": "814 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A43EC3F2C967B", "submission_order": 1, "result": "AC", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Bell state generate\n    # CNOT + H\n\n    qc.h(0)  # Hadamard gate\n    qc.cx(0, 1)  # CNOT gate\n\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(qc)\n'''"}
{"problem": "QPC001_A3", "user": "A489840B0889A", "submission_order": 1, "result": "WA", "execution_time": "908 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A489840B0889A", "submission_order": 2, "result": "AC", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A49C57F38DC8E", "submission_order": 1, "result": "WA", "execution_time": "914 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A49C57F38DC8E", "submission_order": 2, "result": "AC", "execution_time": "961 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4AD758F6E6D7", "submission_order": 1, "result": "AC", "execution_time": "972 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4AE4E5CED9B8", "submission_order": 1, "result": "AC", "execution_time": "1516 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4B4008A5EFF8", "submission_order": 1, "result": "RE", "execution_time": "1903 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cn(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4B4008A5EFF8", "submission_order": 2, "result": "WA", "execution_time": "1832 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4B4008A5EFF8", "submission_order": 3, "result": "RE", "execution_time": "1817 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.c(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4B4008A5EFF8", "submission_order": 4, "result": "AC", "execution_time": "1788 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4D1C9D43E512", "submission_order": 1, "result": "WA", "execution_time": "891 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.h(0)\n  qc.cx(1,0)\n  return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4D1C9D43E512", "submission_order": 2, "result": "AC", "execution_time": "904 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.h(0)\n  qc.cx(0,1)\n  return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4D31E673C66C", "submission_order": 1, "result": "AC", "execution_time": "826 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4DE65FDA2F9D", "submission_order": 1, "result": "WA", "execution_time": "1990 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4DE65FDA2F9D", "submission_order": 2, "result": "WA", "execution_time": "2048 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4DE65FDA2F9D", "submission_order": 3, "result": "AC", "execution_time": "2000 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4EC8D4769DB2", "submission_order": 1, "result": "RE", "execution_time": "1660 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A3", "user": "A4EC8D4769DB2", "submission_order": 2, "result": "RE", "execution_time": "1823 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A3", "user": "A4EC8D4769DB2", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\nif __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC001_A3", "user": "A4EC8D4769DB2", "submission_order": 4, "result": "AC", "execution_time": "1787 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A3", "user": "A4F44EA3928FD", "submission_order": 1, "result": "WA", "execution_time": "800 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rxx(math.pi/2, 0, 1)\n    qc.z(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4F44EA3928FD", "submission_order": 2, "result": "AC", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4F61BB0ED629", "submission_order": 1, "result": "AC", "execution_time": "716 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A4F8825D285E9", "submission_order": 1, "result": "AC", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5119A14766D7", "submission_order": 1, "result": "WA", "execution_time": "800 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5119A14766D7", "submission_order": 2, "result": "AC", "execution_time": "896 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A513A4CA15609", "submission_order": 1, "result": "WA", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A513A4CA15609", "submission_order": 2, "result": "AC", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A516E52982D53", "submission_order": 1, "result": "AC", "execution_time": "1401 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5261013F3868", "submission_order": 1, "result": "AC", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A52C53B8843D0", "submission_order": 1, "result": "AC", "execution_time": "916 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A53401F111735", "submission_order": 1, "result": "AC", "execution_time": "991 ms", "memory": "90 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n \n    return qc\n# %%\n'''"}
{"problem": "QPC001_A3", "user": "A54003EEB80D6", "submission_order": 1, "result": "AC", "execution_time": "898 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A540863AB81E2", "submission_order": 1, "result": "AC", "execution_time": "1951 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A54614B2CC576", "submission_order": 1, "result": "WA", "execution_time": "1735 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(2):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A54614B2CC576", "submission_order": 2, "result": "AC", "execution_time": "1637 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A546525807469", "submission_order": 1, "result": "AC", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A54919658A79E", "submission_order": 1, "result": "AC", "execution_time": "1027 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5495C6356E98", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A54CD0677A701", "submission_order": 1, "result": "AC", "execution_time": "874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A54E019A0FB51", "submission_order": 1, "result": "WA", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A54E019A0FB51", "submission_order": 2, "result": "AC", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A56564AB2729F", "submission_order": 1, "result": "AC", "execution_time": "1475 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A56DC1C906E42", "submission_order": 1, "result": "AC", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5967B8E5F61A", "submission_order": 1, "result": "WA", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5967B8E5F61A", "submission_order": 2, "result": "AC", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5B453294CB8C", "submission_order": 1, "result": "AC", "execution_time": "1389 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5BFAA5DA8995", "submission_order": 1, "result": "RE", "execution_time": "874 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(3)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5BFAA5DA8995", "submission_order": 2, "result": "RE", "execution_time": "888 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(3)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5BFAA5DA8995", "submission_order": 3, "result": "AC", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1) \n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5C24D953DB21", "submission_order": 1, "result": "AC", "execution_time": "801 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5CC52CBE672E", "submission_order": 1, "result": "AC", "execution_time": "1202 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5D08CC535D2F", "submission_order": 1, "result": "AC", "execution_time": "1919 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5D0EEAF10A19", "submission_order": 1, "result": "AC", "execution_time": "927 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5D3D6EC7391F", "submission_order": 1, "result": "AC", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5D4F2DD7328E", "submission_order": 1, "result": "AC", "execution_time": "1747 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A3", "user": "A5E623148D3E6", "submission_order": 1, "result": "AC", "execution_time": "1855 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5ED241E98046", "submission_order": 1, "result": "RE", "execution_time": "812 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.measure([0, 1], [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5ED241E98046", "submission_order": 2, "result": "AC", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5F0AB451BC8B", "submission_order": 1, "result": "AC", "execution_time": "1728 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A5FA75AFD2A38", "submission_order": 1, "result": "AC", "execution_time": "1486 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6040860BA6A2", "submission_order": 1, "result": "AC", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A623F90005AF5", "submission_order": 1, "result": "RE", "execution_time": "756 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.mcx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A623F90005AF5", "submission_order": 2, "result": "AC", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6287D361CA3D", "submission_order": 1, "result": "AC", "execution_time": "1169 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A62A829203E79", "submission_order": 1, "result": "AC", "execution_time": "1171 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A638819FFDA8A", "submission_order": 1, "result": "AC", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A63B6DA18942B", "submission_order": 1, "result": "AC", "execution_time": "1903 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A63EA9BB14AD7", "submission_order": 1, "result": "RE", "execution_time": "789 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.x(2)\n    qc.h(1)\n    qc.h(2)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A63EA9BB14AD7", "submission_order": 2, "result": "RE", "execution_time": "727 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(01)\n    qc.x(10)\n    qc.h(01)\n    qc.h(10)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A63EA9BB14AD7", "submission_order": 3, "result": "WA", "execution_time": "850 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A63EA9BB14AD7", "submission_order": 4, "result": "WA", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A63EA9BB14AD7", "submission_order": 5, "result": "AC", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A64A936204F90", "submission_order": 1, "result": "AC", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A659353729249", "submission_order": 1, "result": "AC", "execution_time": "1010 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A65CAE832C4F1", "submission_order": 1, "result": "UGE", "execution_time": "794 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    initial_state = [0.+1.j/2**0.5,1/2**0.5+0.j]\n    qc.initialize(initial_state, 0)\n    qc.initialize(initial_state, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A65CAE832C4F1", "submission_order": 2, "result": "AC", "execution_time": "923 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A694FD4D815A4", "submission_order": 1, "result": "AC", "execution_time": "1142 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A696AAB8A7E7A", "submission_order": 1, "result": "RE", "execution_time": "1474 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A696AAB8A7E7A", "submission_order": 2, "result": "AC", "execution_time": "1466 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6AA8C4BFFA2E", "submission_order": 1, "result": "AC", "execution_time": "1548 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6B50FD0F2F68", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rxx(-np.pi/2,0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6B50FD0F2F68", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6B50FD0F2F68", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6B50FD0F2F68", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6B50FD0F2F68", "submission_order": 5, "result": "RE", "execution_time": "717 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.c(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6B50FD0F2F68", "submission_order": 6, "result": "AC", "execution_time": "920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6E2CF5F16F5E", "submission_order": 1, "result": "AC", "execution_time": "1746 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6F137E57A9D4", "submission_order": 1, "result": "AC", "execution_time": "1779 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6F6CF254ED15", "submission_order": 1, "result": "AC", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6FBA2068D145", "submission_order": 1, "result": "AC", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6FD54A506572", "submission_order": 1, "result": "AC", "execution_time": "1305 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A6FE31B262137", "submission_order": 1, "result": "AC", "execution_time": "888 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A70FF00DFAF85", "submission_order": 1, "result": "AC", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A715AE4AB5083", "submission_order": 1, "result": "AC", "execution_time": "1581 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A715E7D619A9A", "submission_order": 1, "result": "AC", "execution_time": "1368 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A730E08055037", "submission_order": 1, "result": "AC", "execution_time": "1479 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7397A3A2C8CC", "submission_order": 1, "result": "AC", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A73D1AC34DC3E", "submission_order": 1, "result": "AC", "execution_time": "1115 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A74438F2CF228", "submission_order": 1, "result": "AC", "execution_time": "1308 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7451BD839599", "submission_order": 1, "result": "AC", "execution_time": "795 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7484EDFEEFD3", "submission_order": 1, "result": "AC", "execution_time": "1981 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7505566A5E4F", "submission_order": 1, "result": "AC", "execution_time": "960 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A755D9BA3EAF5", "submission_order": 1, "result": "AC", "execution_time": "1092 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7614153773E8", "submission_order": 1, "result": "AC", "execution_time": "826 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7655642C88AF", "submission_order": 1, "result": "AC", "execution_time": "1352 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A77BF6C690CC6", "submission_order": 1, "result": "AC", "execution_time": "890 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A77E5DEBA207A", "submission_order": 1, "result": "AC", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A795A5E18F005", "submission_order": 1, "result": "AC", "execution_time": "1815 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7A2A2176F9B7", "submission_order": 1, "result": "RE", "execution_time": "1448 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7A2A2176F9B7", "submission_order": 2, "result": "WA", "execution_time": "1517 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7A2A2176F9B7", "submission_order": 3, "result": "AC", "execution_time": "1709 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7A68E7D0441F", "submission_order": 1, "result": "AC", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7AED7CCECBEE", "submission_order": 1, "result": "AC", "execution_time": "890 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7B12504AB7AA", "submission_order": 1, "result": "AC", "execution_time": "1629 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7B3FBEFA451A", "submission_order": 1, "result": "AC", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7B542B3F1AA4", "submission_order": 1, "result": "WA", "execution_time": "1036 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(0, 1)\n    qc.cnot(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7B542B3F1AA4", "submission_order": 2, "result": "WA", "execution_time": "1482 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.z(1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7B542B3F1AA4", "submission_order": 3, "result": "AC", "execution_time": "1024 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7B80F30D05E7", "submission_order": 1, "result": "AC", "execution_time": "1943 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7C3D211962B9", "submission_order": 1, "result": "AC", "execution_time": "1557 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7C8C7A3EDFFC", "submission_order": 1, "result": "AC", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7CEF43601961", "submission_order": 1, "result": "AC", "execution_time": "1848 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7D09DA91F4D1", "submission_order": 1, "result": "AC", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7D2B469C3654", "submission_order": 1, "result": "RE", "execution_time": "739 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qx.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7D2B469C3654", "submission_order": 2, "result": "AC", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7D2FF1410D30", "submission_order": 1, "result": "RE", "execution_time": "1841 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7D2FF1410D30", "submission_order": 2, "result": "AC", "execution_time": "1942 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A7D57C9D19D82", "submission_order": 1, "result": "AC", "execution_time": "803 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A8008D8D5BDE5", "submission_order": 1, "result": "AC", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A81F26B5C245D", "submission_order": 1, "result": "AC", "execution_time": "862 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A83E582ACBDEF", "submission_order": 1, "result": "AC", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A849136779A2E", "submission_order": 1, "result": "RE", "execution_time": "1250 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0, 0)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A849136779A2E", "submission_order": 2, "result": "AC", "execution_time": "1336 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A84C906C074F5", "submission_order": 1, "result": "AC", "execution_time": "1851 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A8554854EBB22", "submission_order": 1, "result": "AC", "execution_time": "1006 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A85D89946E510", "submission_order": 1, "result": "WA", "execution_time": "768 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A85D89946E510", "submission_order": 2, "result": "AC", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A86282D8EEFDA", "submission_order": 1, "result": "AC", "execution_time": "831 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A86BDDB986AFB", "submission_order": 1, "result": "RE", "execution_time": "773 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,3])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A86BDDB986AFB", "submission_order": 2, "result": "RE", "execution_time": "877 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,3])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A86BDDB986AFB", "submission_order": 3, "result": "RE", "execution_time": "1574 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0,3)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A86BDDB986AFB", "submission_order": 4, "result": "RE", "execution_time": "763 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from qiskit import QuantumRegister\n    q = QuantumRegister(2)\n    qc.h(q[0])\n    qc.cx(q[0],q[1])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A86BDDB986AFB", "submission_order": 5, "result": "RE", "execution_time": "731 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    q = QuantumRegister(2)\n    qc.h(q[0])\n    qc.cx(q[0],q[1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A86BDDB986AFB", "submission_order": 6, "result": "AC", "execution_time": "1791 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    q = QuantumRegister(2)\n    qc.h(0)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A87F99D2DD4D5", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A8866C5EA3D8F", "submission_order": 1, "result": "AC", "execution_time": "1911 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A8CA854D493B2", "submission_order": 1, "result": "AC", "execution_time": "687 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A8E801846EF3C", "submission_order": 1, "result": "AC", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A8F1645BA044C", "submission_order": 1, "result": "WA", "execution_time": "848 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0) # Pauli-X gate \n    qc.h(0) # Hadamard gate \n    qc.cx(0,1) # CNOT gate\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A8F1645BA044C", "submission_order": 2, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0) # Hadamard gate \n    qc.cx(0,1) # CNOT gate\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A8F761E395999", "submission_order": 1, "result": "AC", "execution_time": "1597 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, CXGate\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\t# Write your code here:\n\tqc.append(HGate(), [0])\n\tqc.append(CXGate(), [0, 1])\n\treturn qc\n'''"}
{"problem": "QPC001_A3", "user": "A90A26FDC895B", "submission_order": 1, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A90FDCBAE79C8", "submission_order": 1, "result": "AC", "execution_time": "1649 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(control_qubit=0, target_qubit=1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A914114959E51", "submission_order": 1, "result": "AC", "execution_time": "1135 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A914502314BCA", "submission_order": 1, "result": "AC", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cnot(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9201AD19581B", "submission_order": 1, "result": "AC", "execution_time": "1463 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Apply Hadamard to qubit 0\n    qc.h(0)\n    # Apply CNOT with qubit 0 as control and qubit 1 as target\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9223301A2CA5", "submission_order": 1, "result": "UGE", "execution_time": "1325 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, MCMT\nimport numpy as np\n\ndef solve():\n    q = QuantumCircuit(2)\n\n    q.h(0)\n    q.append(MCMT(XGate(), 1, 1), [0, 1])\n\n    return q\n'''"}
{"problem": "QPC001_A3", "user": "A9223301A2CA5", "submission_order": 2, "result": "AC", "execution_time": "1331 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, MCMT\nimport numpy as np\n\ndef solve():\n    q = QuantumCircuit(2)\n\n    q.h(0)\n    mcx = XGate().control(1)\n    q.append(mcx, [0, 1])\n\n    return q\n'''"}
{"problem": "QPC001_A3", "user": "A9341B3E31619", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cnot(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A949FFF2D82F9", "submission_order": 1, "result": "WA", "execution_time": "1901 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A949FFF2D82F9", "submission_order": 2, "result": "AC", "execution_time": "1914 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A95CC105B29B9", "submission_order": 1, "result": "AC", "execution_time": "1937 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A966FC98A7DD0", "submission_order": 1, "result": "WA", "execution_time": "952 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A966FC98A7DD0", "submission_order": 2, "result": "AC", "execution_time": "867 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A96BCFAE1F127", "submission_order": 1, "result": "AC", "execution_time": "1401 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9769BF2A94B8", "submission_order": 1, "result": "AC", "execution_time": "1281 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A97B177956E0B", "submission_order": 1, "result": "AC", "execution_time": "974 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(0)\n    qc.cnot(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A97D2CFFFAF8B", "submission_order": 1, "result": "AC", "execution_time": "1592 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A97F1E09109F7", "submission_order": 1, "result": "WA", "execution_time": "961 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A97F1E09109F7", "submission_order": 2, "result": "AC", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A98A20EA55D7F", "submission_order": 1, "result": "AC", "execution_time": "1533 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    # qc.cx(control qubit, target qubit)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A98DE7F15AC54", "submission_order": 1, "result": "WA", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A98DE7F15AC54", "submission_order": 2, "result": "AC", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A98FE58F0B967", "submission_order": 1, "result": "AC", "execution_time": "1430 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A99B0A52A214D", "submission_order": 1, "result": "AC", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A99E582B6ABEE", "submission_order": 1, "result": "AC", "execution_time": "1184 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9AC561B2F19C", "submission_order": 1, "result": "AC", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9AD736055802", "submission_order": 1, "result": "AC", "execution_time": "889 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)        # Apply Hadamard gate to the first qubit\n    qc.cx(0, 1)    # Apply CNOT gate with the first qubit as control and the second as target\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9B286A59F0B4", "submission_order": 1, "result": "AC", "execution_time": "1784 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9C751E2E475F", "submission_order": 1, "result": "AC", "execution_time": "1859 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9D4F07AA40C3", "submission_order": 1, "result": "AC", "execution_time": "891 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9EB3CE04D9C1", "submission_order": 1, "result": "AC", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    # 1番目の量子ビットを制御量子ビットとして、2番目の量子ビットにCNOTゲートを適用\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9FBFC0BFF0AD", "submission_order": 1, "result": "WA", "execution_time": "1705 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9FBFC0BFF0AD", "submission_order": 2, "result": "AC", "execution_time": "1645 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9FD859012BE4", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "A9FDD085D3CCA", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport numpy as np\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rxx(np.pi/2,0,1)\n \n    return qc\n\nqc = solve()\nprint(qc)\nprint(Statevector(qc))\n'''"}
{"problem": "QPC001_A3", "user": "A9FDD085D3CCA", "submission_order": 2, "result": "AC", "execution_time": "1425 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit.quantum_info import Statevector\nimport numpy as np\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.rxx(np.pi/2,0,1)\n    qc.p(np.pi/2,1)\n \n    return qc\n\nqc = solve()\nprint(qc)\n#print(Statevector(qc))\n'''"}
{"problem": "QPC001_A3", "user": "AA02E905C3E31", "submission_order": 1, "result": "WA", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1) # 1を+に\n    # CNOT |0+>\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA02E905C3E31", "submission_order": 2, "result": "AC", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1) # 1を+に\n    # CNOT |0+>\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA04C38D4669F", "submission_order": 1, "result": "AC", "execution_time": "2188 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA0E100B35440", "submission_order": 1, "result": "AC", "execution_time": "1607 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA141DEC26D39", "submission_order": 1, "result": "AC", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA2482F2FADE2", "submission_order": 1, "result": "AC", "execution_time": "1272 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA2903BCD4844", "submission_order": 1, "result": "AC", "execution_time": "1491 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA36CE56C9ECA", "submission_order": 1, "result": "AC", "execution_time": "1722 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA384B9C89BC8", "submission_order": 1, "result": "AC", "execution_time": "1787 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA579AF180AD7", "submission_order": 1, "result": "RE", "execution_time": "1327 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cnot(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA579AF180AD7", "submission_order": 2, "result": "AC", "execution_time": "1465 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA62D6DECE5E8", "submission_order": 1, "result": "AC", "execution_time": "1413 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA673594A746D", "submission_order": 1, "result": "WA", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA673594A746D", "submission_order": 2, "result": "AC", "execution_time": "1699 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA6A23AA0EA6C", "submission_order": 1, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA76C0B4A2E54", "submission_order": 1, "result": "AC", "execution_time": "1457 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA7C9BAFC79C9", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA7D9527FB978", "submission_order": 1, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA8266DC8BCED", "submission_order": 1, "result": "AC", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AA91CAC6772C1", "submission_order": 1, "result": "AC", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AAC63526E966C", "submission_order": 1, "result": "AC", "execution_time": "1425 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AAD0086BBEAE5", "submission_order": 1, "result": "WA", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AAD0086BBEAE5", "submission_order": 2, "result": "WA", "execution_time": "898 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AAD0086BBEAE5", "submission_order": 3, "result": "AC", "execution_time": "900 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AAD771A61BF2B", "submission_order": 1, "result": "AC", "execution_time": "1117 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AADD6F22C0DAE", "submission_order": 1, "result": "AC", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AAFA8E4F6D117", "submission_order": 1, "result": "WA", "execution_time": "1917 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AAFA8E4F6D117", "submission_order": 2, "result": "AC", "execution_time": "1616 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 1, "result": "WA", "execution_time": "890 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cnot(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 2, "result": "WA", "execution_time": "819 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 3, "result": "WA", "execution_time": "1788 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 4, "result": "WA", "execution_time": "855 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.z(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 5, "result": "WA", "execution_time": "808 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 6, "result": "WA", "execution_time": "902 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 7, "result": "WA", "execution_time": "910 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 8, "result": "WA", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 9, "result": "WA", "execution_time": "914 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.x(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 10, "result": "WA", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.x(1)\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 11, "result": "WA", "execution_time": "1034 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 12, "result": "WA", "execution_time": "990 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(range(2))\n    qc.i(range(2))\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 13, "result": "WA", "execution_time": "977 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(range(2))\n    qc.z(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 14, "result": "WA", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(range(2))\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 15, "result": "RE", "execution_time": "743 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(range(2))\n    qc.id()\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 16, "result": "RE", "execution_time": "724 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.id()\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 17, "result": "RE", "execution_time": "1584 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.id()\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 18, "result": "RE", "execution_time": "815 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.id()\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 19, "result": "WA", "execution_time": "867 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.id(0)\n    qc.id(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 20, "result": "RE", "execution_time": "1594 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(range(2))\n    qc.measure([0,1],[1,0])\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 21, "result": "RE", "execution_time": "1328 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.measure([0,1],[1,0])\n    qc.h(range(2))    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 22, "result": "RE", "execution_time": "815 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)  \n    qc.measure([0,1],[1,0])\n    #qc.h(range(2))    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 23, "result": "RE", "execution_time": "795 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)  \n    qc.measure([0,1])\n    #qc.h(range(2))    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB0F3DB8DD5F3", "submission_order": 24, "result": "AC", "execution_time": "902 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)  \n   # qc.measure([0,1])\n    #qc.h(range(2))    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB1361B406876", "submission_order": 1, "result": "AC", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB160C6D21826", "submission_order": 1, "result": "AC", "execution_time": "1432 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB349E967C006", "submission_order": 1, "result": "AC", "execution_time": "1124 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB368771BCD34", "submission_order": 1, "result": "AC", "execution_time": "1950 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB3B077635FEE", "submission_order": 1, "result": "AC", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB3BFA3D3F45B", "submission_order": 1, "result": "AC", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB3E25AE36F97", "submission_order": 1, "result": "AC", "execution_time": "1704 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AB471FFAB3C6A", "submission_order": 1, "result": "AC", "execution_time": "1380 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABA10BC532FC9", "submission_order": 1, "result": "AC", "execution_time": "1000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABA16F4121A7A", "submission_order": 1, "result": "AC", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABA6F8D8B8B63", "submission_order": 1, "result": "RE", "execution_time": "1500 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(n))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABA6F8D8B8B63", "submission_order": 2, "result": "WA", "execution_time": "1644 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABA6F8D8B8B63", "submission_order": 3, "result": "WA", "execution_time": "1573 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABA6F8D8B8B63", "submission_order": 4, "result": "AC", "execution_time": "1565 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABA8F34D716E4", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABAFD39CB67EE", "submission_order": 1, "result": "AC", "execution_time": "886 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABBAB7315BFD0", "submission_order": 1, "result": "WA", "execution_time": "1904 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(range(2))\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABBAB7315BFD0", "submission_order": 2, "result": "WA", "execution_time": "945 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABBAB7315BFD0", "submission_order": 3, "result": "AC", "execution_time": "1056 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC183539CE6E", "submission_order": 1, "result": "RE", "execution_time": "824 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.append(HGate(),0)\n    qc.append(HGate(),1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC5A7E978D9B", "submission_order": 1, "result": "RE", "execution_time": "740 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(q[1],q[0])\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC5A7E978D9B", "submission_order": 2, "result": "AC", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC81D5525C86", "submission_order": 1, "result": "RE", "execution_time": "779 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC81D5525C86", "submission_order": 2, "result": "AC", "execution_time": "892 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC898E933C8A", "submission_order": 1, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC898E933C8A", "submission_order": 2, "result": "WA", "execution_time": "1011 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC898E933C8A", "submission_order": 3, "result": "WA", "execution_time": "1436 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC898E933C8A", "submission_order": 4, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 1, "result": "WA", "execution_time": "1942 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.p(math.pi/4,0)\n    qc.p(math.pi/4,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 2, "result": "WA", "execution_time": "1832 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.p(math.pi/4,0)\n    qc.p(math.pi/4,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 3, "result": "WA", "execution_time": "1839 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 4, "result": "WA", "execution_time": "1835 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 5, "result": "RE", "execution_time": "1652 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.R(math.pi/2,0)\n    # qc.R(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 6, "result": "RE", "execution_time": "1887 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(2)\n\n    # qc.R(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 7, "result": "RE", "execution_time": "1863 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,2)\n\n    # qc.R(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 8, "result": "RE", "execution_time": "1786 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1)\n\n    # qc.R(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABC91CF96B04D", "submission_order": 9, "result": "AC", "execution_time": "1792 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    # qc.R(0)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABCC328CB2E79", "submission_order": 1, "result": "WA", "execution_time": "1626 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABCC328CB2E79", "submission_order": 2, "result": "RE", "execution_time": "1601 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABCC328CB2E79", "submission_order": 3, "result": "RE", "execution_time": "1479 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABCC328CB2E79", "submission_order": 4, "result": "RE", "execution_time": "1519 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABCC328CB2E79", "submission_order": 5, "result": "AC", "execution_time": "1593 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABD949D6EA7E6", "submission_order": 1, "result": "AC", "execution_time": "1475 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABDF89A8D7453", "submission_order": 1, "result": "AC", "execution_time": "928 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\tqc.h(0)\n\tqc.cx(0, 1)\n\treturn qc\n'''"}
{"problem": "QPC001_A3", "user": "ABE4FC626CFA2", "submission_order": 1, "result": "WA", "execution_time": "844 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABE4FC626CFA2", "submission_order": 2, "result": "WA", "execution_time": "1149 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABE4FC626CFA2", "submission_order": 3, "result": "AC", "execution_time": "1353 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABFE19FE1BD6D", "submission_order": 1, "result": "AC", "execution_time": "1663 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABFF8D97768E4", "submission_order": 1, "result": "WA", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABFF8D97768E4", "submission_order": 2, "result": "WA", "execution_time": "822 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ABFF8D97768E4", "submission_order": 3, "result": "AC", "execution_time": "938 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC0437ED0B533", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC1BA1C761121", "submission_order": 1, "result": "RE", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC1BA1C761121", "submission_order": 2, "result": "AC", "execution_time": "1377 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC25E52219A61", "submission_order": 1, "result": "AC", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC2A754F3BFB5", "submission_order": 1, "result": "AC", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC2C89DE26992", "submission_order": 1, "result": "AC", "execution_time": "840 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC2CE9C23F091", "submission_order": 1, "result": "AC", "execution_time": "2160 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC340FC43803A", "submission_order": 1, "result": "RE", "execution_time": "1332 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.CNOT(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC340FC43803A", "submission_order": 2, "result": "RE", "execution_time": "1386 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.CNOT(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC340FC43803A", "submission_order": 3, "result": "RE", "execution_time": "1243 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.CNOT(0,1)\n    cirq.measure(q0, q1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC340FC43803A", "submission_order": 4, "result": "RE", "execution_time": "1269 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    cirq.measure(q0, q1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC340FC43803A", "submission_order": 5, "result": "AC", "execution_time": "1402 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC5FD5CDBBEC6", "submission_order": 1, "result": "AC", "execution_time": "922 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC67792C76383", "submission_order": 1, "result": "WA", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC67792C76383", "submission_order": 2, "result": "WA", "execution_time": "1227 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC67792C76383", "submission_order": 3, "result": "WA", "execution_time": "814 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC6A674F65C80", "submission_order": 1, "result": "WA", "execution_time": "1963 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC6A674F65C80", "submission_order": 2, "result": "AC", "execution_time": "2039 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC6ED183DF39F", "submission_order": 1, "result": "AC", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC7B7A0868BC2", "submission_order": 1, "result": "AC", "execution_time": "1171 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AC9AABFB3C2DE", "submission_order": 1, "result": "AC", "execution_time": "822 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ACA2FDD96377D", "submission_order": 1, "result": "AC", "execution_time": "826 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ACB2C50E9C7C4", "submission_order": 1, "result": "AC", "execution_time": "1058 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ACB93186286A1", "submission_order": 1, "result": "AC", "execution_time": "1956 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ACBAB6460B3E6", "submission_order": 1, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ACE983293F590", "submission_order": 1, "result": "AC", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ACE9BAFC64EFF", "submission_order": 1, "result": "AC", "execution_time": "1152 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ACEFE684D143B", "submission_order": 1, "result": "AC", "execution_time": "1033 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD253C45955CB", "submission_order": 1, "result": "WA", "execution_time": "1449 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD253C45955CB", "submission_order": 2, "result": "RE", "execution_time": "1292 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0, 1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD253C45955CB", "submission_order": 3, "result": "WA", "execution_time": "1443 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD253C45955CB", "submission_order": 4, "result": "AC", "execution_time": "1390 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD3216E1D2315", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD38C4674BA19", "submission_order": 1, "result": "WA", "execution_time": "786 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(1)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD38C4674BA19", "submission_order": 2, "result": "AC", "execution_time": "759 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD53DE46D5A07", "submission_order": 1, "result": "AC", "execution_time": "1597 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD5B7BAD2A4D6", "submission_order": 1, "result": "RE", "execution_time": "1231 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    \n    # Write your code here:\n    qc.h(0)\n    qc.cx(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD5B7BAD2A4D6", "submission_order": 2, "result": "AC", "execution_time": "1212 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    \n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD6DA1028A842", "submission_order": 1, "result": "WA", "execution_time": "833 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD6DA1028A842", "submission_order": 2, "result": "AC", "execution_time": "969 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD790E5976AAA", "submission_order": 1, "result": "AC", "execution_time": "1020 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD7E3CE12E406", "submission_order": 1, "result": "RE", "execution_time": "1327 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.append(\n        HGate(),  # New HGate instruction\n        [0]       # Apply to qubit 0\n        )\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD7E3CE12E406", "submission_order": 2, "result": "RE", "execution_time": "746 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.append(\n        HGate(),  # New HGate instruction\n        [0]       # Apply to qubit 0\n        )\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD7E3CE12E406", "submission_order": 3, "result": "AC", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD872542B61F9", "submission_order": 1, "result": "AC", "execution_time": "1514 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD8996837861D", "submission_order": 1, "result": "AC", "execution_time": "1667 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD979C949FE7D", "submission_order": 1, "result": "WA", "execution_time": "1128 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD979C949FE7D", "submission_order": 2, "result": "RE", "execution_time": "1403 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(qc[0], qc[1])\n    qc.cx(qc[1], qc[0])\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD979C949FE7D", "submission_order": 3, "result": "RE", "execution_time": "1431 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h[range(0, 2)]\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD979C949FE7D", "submission_order": 4, "result": "RE", "execution_time": "1448 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h[range(0, 2)]\n    qc.cx(1, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD979C949FE7D", "submission_order": 5, "result": "RE", "execution_time": "1420 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD979C949FE7D", "submission_order": 6, "result": "AC", "execution_time": "1469 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AD9F104FB3618", "submission_order": 1, "result": "AC", "execution_time": "1467 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADB739B515546", "submission_order": 1, "result": "RE", "execution_time": "779 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADB739B515546", "submission_order": 2, "result": "AC", "execution_time": "821 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADCD2F4700646", "submission_order": 1, "result": "AC", "execution_time": "2003 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADD655857B126", "submission_order": 1, "result": "AC", "execution_time": "1348 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADE80ED1D3A65", "submission_order": 1, "result": "AC", "execution_time": "896 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADEE40620EC6E", "submission_order": 1, "result": "AC", "execution_time": "1350 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADEF80A0B576F", "submission_order": 1, "result": "AC", "execution_time": "1645 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADF95ABBEFECE", "submission_order": 1, "result": "AC", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "ADFF1A2DA57A4", "submission_order": 1, "result": "AC", "execution_time": "1852 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE07F5E464A3D", "submission_order": 1, "result": "AC", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE0B912BCAC96", "submission_order": 1, "result": "RE", "execution_time": "1816 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.CNOT(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE0B912BCAC96", "submission_order": 2, "result": "AC", "execution_time": "1745 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE14B39E20B63", "submission_order": 1, "result": "AC", "execution_time": "1432 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE192BE900AE7", "submission_order": 1, "result": "AC", "execution_time": "1367 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE2314F64F65F", "submission_order": 1, "result": "AC", "execution_time": "919 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0); qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE2450625804C", "submission_order": 1, "result": "RE", "execution_time": "1865 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE262F71EB52C", "submission_order": 1, "result": "AC", "execution_time": "819 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE365928F4594", "submission_order": 1, "result": "AC", "execution_time": "1454 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE45128286BC0", "submission_order": 1, "result": "AC", "execution_time": "1394 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE46D4A058E3F", "submission_order": 1, "result": "AC", "execution_time": "1362 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE5062EF63BC6", "submission_order": 1, "result": "AC", "execution_time": "954 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE654006E72AC", "submission_order": 1, "result": "RE", "execution_time": "692 ms", "memory": "79 MiB", "code": "'''python\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE654006E72AC", "submission_order": 2, "result": "AC", "execution_time": "810 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE71E0C9AA4C9", "submission_order": 1, "result": "AC", "execution_time": "919 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE78E0A183100", "submission_order": 1, "result": "AC", "execution_time": "1403 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE89A1A124ADB", "submission_order": 1, "result": "AC", "execution_time": "1424 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE957BCE06464", "submission_order": 1, "result": "RE", "execution_time": "1862 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(control=0, target=1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE957BCE06464", "submission_order": 2, "result": "AC", "execution_time": "1997 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)        # Hadamard on qubit 0\n    qc.cx(0, 1)    # CNOT from qubit 0 to qubit 1\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AE98EB6F0FDBF", "submission_order": 1, "result": "AC", "execution_time": "1391 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEA24815C58F4", "submission_order": 1, "result": "AC", "execution_time": "807 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEA27298BD7E1", "submission_order": 1, "result": "AC", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEB51E9DECDCF", "submission_order": 1, "result": "RE", "execution_time": "827 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(2)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEB51E9DECDCF", "submission_order": 2, "result": "RE", "execution_time": "1218 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    q = QuantumCircuit(2)\n    c = ClassicalResister(2)\n    qc=QuantumCircuit(q,c)\n    qc.h(q[0])\n    qc.cx(q[0],q[1])\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEB51E9DECDCF", "submission_order": 3, "result": "AC", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEB6D665477A6", "submission_order": 1, "result": "AC", "execution_time": "1323 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEBFCA09FF064", "submission_order": 1, "result": "AC", "execution_time": "1503 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AED57309C2453", "submission_order": 1, "result": "AC", "execution_time": "908 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AED8A3E097D18", "submission_order": 1, "result": "WA", "execution_time": "1891 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AED8A3E097D18", "submission_order": 2, "result": "AC", "execution_time": "1753 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AED8BF21CB362", "submission_order": 1, "result": "AC", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    # アダマールゲートを1つ目の量子ビットに適用\n    qc.h(0)\n\n    # 制御NOTゲートを適用（1つ目の量子ビットが制御、2つ目の量子ビットがターゲット）\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEE1F834132E3", "submission_order": 1, "result": "AC", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEF4FEAB2B7D1", "submission_order": 1, "result": "WA", "execution_time": "1481 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEF4FEAB2B7D1", "submission_order": 2, "result": "AC", "execution_time": "1452 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEF9F520748D8", "submission_order": 1, "result": "RE", "execution_time": "703 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h([0, 3])\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEF9F520748D8", "submission_order": 2, "result": "RE", "execution_time": "847 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(range(0, 4, 3))\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEF9F520748D8", "submission_order": 3, "result": "RE", "execution_time": "761 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(3)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEF9F520748D8", "submission_order": 4, "result": "WA", "execution_time": "787 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(range(2))\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AEF9F520748D8", "submission_order": 5, "result": "AC", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF01479FAEAAC", "submission_order": 1, "result": "AC", "execution_time": "1641 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF01D347945C6", "submission_order": 1, "result": "RE", "execution_time": "744 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0).cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF01D347945C6", "submission_order": 2, "result": "AC", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF1A0A5053CD9", "submission_order": 1, "result": "AC", "execution_time": "1105 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF22F59ECDA6E", "submission_order": 1, "result": "WA", "execution_time": "901 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.x(0)\n  qc.cx(0, 1)\n  return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF22F59ECDA6E", "submission_order": 2, "result": "WA", "execution_time": "951 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.x(0)\n  qc.cx(1, 0)\n  return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF22F59ECDA6E", "submission_order": 3, "result": "AC", "execution_time": "814 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.h(0)\n  qc.cx(0, 1)\n  return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF2CA1BB5927E", "submission_order": 1, "result": "AC", "execution_time": "1770 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF2DA61C3A95C", "submission_order": 1, "result": "RE", "execution_time": "1343 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF2DA61C3A95C", "submission_order": 2, "result": "AC", "execution_time": "1408 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF3D1F4E7333E", "submission_order": 1, "result": "AC", "execution_time": "947 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF48B7B8FBDD1", "submission_order": 1, "result": "AC", "execution_time": "1487 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF49431FF757F", "submission_order": 1, "result": "AC", "execution_time": "951 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF4C2A33287E3", "submission_order": 1, "result": "AC", "execution_time": "1516 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF54C16A8DC8F", "submission_order": 1, "result": "RE", "execution_time": "743 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF54C16A8DC8F", "submission_order": 2, "result": "WA", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF5CAC7E6CEF4", "submission_order": 1, "result": "RE", "execution_time": "1619 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF5CAC7E6CEF4", "submission_order": 2, "result": "RE", "execution_time": "1586 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF5CAC7E6CEF4", "submission_order": 3, "result": "RE", "execution_time": "1614 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(0,1)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF5CAC7E6CEF4", "submission_order": 4, "result": "RE", "execution_time": "1635 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF5CAC7E6CEF4", "submission_order": 5, "result": "RE", "execution_time": "1463 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF5CAC7E6CEF4", "submission_order": 6, "result": "AC", "execution_time": "1700 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF7D24BD79D14", "submission_order": 1, "result": "AC", "execution_time": "859 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF9BECE299C2D", "submission_order": 1, "result": "AC", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AF9F3EC778E2D", "submission_order": 1, "result": "AC", "execution_time": "1571 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0])\n    qc.cx([0], [1])\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFA0483A8D2FA", "submission_order": 1, "result": "WA", "execution_time": "1361 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFA0483A8D2FA", "submission_order": 2, "result": "WA", "execution_time": "1364 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFA0483A8D2FA", "submission_order": 3, "result": "AC", "execution_time": "1332 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFA590DBD139D", "submission_order": 1, "result": "AC", "execution_time": "2055 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFBEBCA778F68", "submission_order": 1, "result": "AC", "execution_time": "1641 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFC2BECBDE089", "submission_order": 1, "result": "AC", "execution_time": "1498 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFD6D2E98DCEF", "submission_order": 1, "result": "AC", "execution_time": "1429 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFDA2C39051F1", "submission_order": 1, "result": "AC", "execution_time": "1444 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n\n    qc.cx(0,1)\n \n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFE3EC489E38C", "submission_order": 1, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFE3EC489E38C", "submission_order": 2, "result": "WA", "execution_time": "818 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFE3EC489E38C", "submission_order": 3, "result": "AC", "execution_time": "859 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFE80EC40AC3B", "submission_order": 1, "result": "RE", "execution_time": "1521 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.x(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFE80EC40AC3B", "submission_order": 2, "result": "WA", "execution_time": "1667 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A3", "user": "AFE80EC40AC3B", "submission_order": 3, "result": "AC", "execution_time": "1565 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A00F4A659A162", "submission_order": 1, "result": "WA", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A00F4A659A162", "submission_order": 2, "result": "WA", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A00F4A659A162", "submission_order": 3, "result": "AC", "execution_time": "954 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A019B4145DE6C", "submission_order": 1, "result": "AC", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A022F22022B09", "submission_order": 1, "result": "AC", "execution_time": "1486 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A033E8B1D8017", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A035461C3F628", "submission_order": 1, "result": "WA", "execution_time": "821 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cp(-pi,0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A042DD14D24FE", "submission_order": 1, "result": "RE", "execution_time": "1399 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0, 1])\n    qc.ccx(0, 1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A042DD14D24FE", "submission_order": 2, "result": "AC", "execution_time": "1439 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    x = QuantumRegister(1)\n    qc.add_register(x)\n    # Write your code here:\n    qc.h([0, 1])\n    qc.ccx(0, 1, x)\n    qc.cx(x, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A04C0A285B066", "submission_order": 1, "result": "AC", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(acos(sqrt(2 / 3)) * 2, 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A052885F30333", "submission_order": 1, "result": "AC", "execution_time": "1381 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A06AC41959C77", "submission_order": 1, "result": "AC", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A06E8AA696C03", "submission_order": 1, "result": "AC", "execution_time": "887 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Bell state generate\n    # CNOT + H\n\n    qc.h(0)  # Hadamard gate\n    qc.h(1)  # hadamard gate\n\n    qc.reset(1)  # reset 1\n\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A07598792692B", "submission_order": 1, "result": "AC", "execution_time": "808 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A08B63B04C9E4", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n    qc.x(1)\n    qc.ch(0, 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0999C8B86AB7", "submission_order": 1, "result": "RE", "execution_time": "1451 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cX(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0999C8B86AB7", "submission_order": 2, "result": "AC", "execution_time": "1568 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A09F95906E5D3", "submission_order": 1, "result": "AC", "execution_time": "808 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A304B7B06CB", "submission_order": 1, "result": "RE", "execution_time": "730 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.ccx(0,1,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A304B7B06CB", "submission_order": 2, "result": "WA", "execution_time": "1176 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A304B7B06CB", "submission_order": 3, "result": "QLE", "execution_time": "770 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(range(3))\n    qc.ccx(0,1,2)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A304B7B06CB", "submission_order": 4, "result": "WA", "execution_time": "1845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A304B7B06CB", "submission_order": 5, "result": "WA", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A304B7B06CB", "submission_order": 6, "result": "WA", "execution_time": "1803 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A304B7B06CB", "submission_order": 7, "result": "WA", "execution_time": "916 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A304B7B06CB", "submission_order": 8, "result": "AC", "execution_time": "792 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0A6A30A2D402", "submission_order": 1, "result": "AC", "execution_time": "1190 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0BB7A2273717", "submission_order": 1, "result": "WA", "execution_time": "1376 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0BB7A2273717", "submission_order": 2, "result": "AC", "execution_time": "1391 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0D93F9007A0D", "submission_order": 1, "result": "RE", "execution_time": "793 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0D93F9007A0D", "submission_order": 2, "result": "WA", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0D93F9007A0D", "submission_order": 3, "result": "AC", "execution_time": "779 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0DA7A500EF51", "submission_order": 1, "result": "RE", "execution_time": "1371 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta,0)\n\n    qc.ch(0,1)\n\n    qc.cx(1,0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0DA7A500EF51", "submission_order": 2, "result": "AC", "execution_time": "1543 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta,0)\n\n    qc.ch(0,1)\n\n    qc.cx(1,0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0E8074F143DF", "submission_order": 1, "result": "RE", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0E8074F143DF", "submission_order": 2, "result": "AC", "execution_time": "1128 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A0F649E0B50E5", "submission_order": 1, "result": "AC", "execution_time": "2187 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A10192CE991DF", "submission_order": 1, "result": "AC", "execution_time": "1704 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.rx(1.57, 0)\n    qc.x(1)\n    qc.ch(0, 1)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A10543861E687", "submission_order": 1, "result": "AC", "execution_time": "1635 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A10EFA7357AA3", "submission_order": 1, "result": "AC", "execution_time": "1984 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(control_qubit=0, target_qubit=1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A118DFB5B0CEB", "submission_order": 1, "result": "AC", "execution_time": "952 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1334CEDF057D", "submission_order": 1, "result": "AC", "execution_time": "1211 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1385EEC45659", "submission_order": 1, "result": "RE", "execution_time": "754 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1385EEC45659", "submission_order": 2, "result": "WA", "execution_time": "1308 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1385EEC45659", "submission_order": 3, "result": "AC", "execution_time": "941 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A13A537ED4816", "submission_order": 1, "result": "AC", "execution_time": "918 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A13A9F8C68C87", "submission_order": 1, "result": "WA", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A13A9F8C68C87", "submission_order": 2, "result": "WA", "execution_time": "1322 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A13A9F8C68C87", "submission_order": 3, "result": "AC", "execution_time": "1439 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A13BAC08C8BD3", "submission_order": 1, "result": "AC", "execution_time": "1538 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A150CF9FB5043", "submission_order": 1, "result": "AC", "execution_time": "1392 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc .cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1565E4CE842C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1565E4CE842C", "submission_order": 2, "result": "AC", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A177793430A1A", "submission_order": 1, "result": "AC", "execution_time": "1903 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(atan(sqrt(1/2))*2, 0)\n    qc.ch(0, 1, ctrl_state=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1879B2888A33", "submission_order": 1, "result": "AC", "execution_time": "1337 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A19448EB7FEA5", "submission_order": 1, "result": "WA", "execution_time": "820 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A19448EB7FEA5", "submission_order": 2, "result": "WA", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A19448EB7FEA5", "submission_order": 3, "result": "WA", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A19D2BF7C04E6", "submission_order": 1, "result": "WA", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A19D2BF7C04E6", "submission_order": 2, "result": "WA", "execution_time": "1873 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A19D2BF7C04E6", "submission_order": 3, "result": "WA", "execution_time": "1440 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A19D2BF7C04E6", "submission_order": 4, "result": "AC", "execution_time": "1657 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A1F6DA043F2", "submission_order": 1, "result": "WA", "execution_time": "822 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(0,1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A1F6DA043F2", "submission_order": 2, "result": "AC", "execution_time": "870 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 1, "result": "RE", "execution_time": "1773 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    theta = 2 * acos(1 / sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 2, "result": "RE", "execution_time": "1983 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    theta = 2 * acos(2 / sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 3, "result": "RE", "execution_time": "1754 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    theta = 2 * acos(sqrt(2/3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 4, "result": "WA", "execution_time": "1818 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    theta = 2 * acos(sqrt(2/3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 5, "result": "WA", "execution_time": "1903 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    theta = 2 * acos(sqrt(2/3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 6, "result": "WA", "execution_time": "1894 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    theta = 2 * acos(sqrt(1/3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 7, "result": "WA", "execution_time": "1848 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # 먼저 qubit 0을 회전시켜서 |0> -> sqrt(2/3)|0> + sqrt(1/3)|1>\n    theta = 2 * acos(sqrt(2/3))  # Ry(theta)|0> = sqrt(2/3)|0> + sqrt(1/3)|1>\n    qc.ry(theta, 0)\n\n    # 이제 qubit 0이 |0>일 때만 qubit 1에 X를 걸어서 |01> 상태 만들기\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 8, "result": "WA", "execution_time": "1902 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.ry(2 * acos(1/sqrt(3)), 0)\n    qc.x(1)\n    qc.cx(0, 1)\n    qc.x(1)\n    qc.ry(2 * acos(sqrt(2/3)), 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1A78F6DAB3AA", "submission_order": 9, "result": "AC", "execution_time": "1942 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1B52D0BD0DA7", "submission_order": 1, "result": "WA", "execution_time": "929 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1B52D0BD0DA7", "submission_order": 2, "result": "WA", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1B52D0BD0DA7", "submission_order": 3, "result": "WA", "execution_time": "1088 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1BD0ED857667", "submission_order": 1, "result": "AC", "execution_time": "1937 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C128EBFDEFA", "submission_order": 1, "result": "WA", "execution_time": "1501 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C128EBFDEFA", "submission_order": 2, "result": "AC", "execution_time": "1436 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * np.arccos(np.sqrt(2/3))  \n    qc.ry(theta, 0)                      \n    qc.x(0)                              \n    qc.cry(np.pi/2, 0, 1)                \n    qc.x(0)                              \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C2D67D50956", "submission_order": 1, "result": "WA", "execution_time": "1325 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C2D67D50956", "submission_order": 2, "result": "AC", "execution_time": "1315 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C3E3217165B", "submission_order": 1, "result": "RE", "execution_time": "1609 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Define the amplitudes a0, a1, a2 (must be normalized)\n    a0 = 1/np.sqrt(3)\n    a1 = 1/np.sqrt(3)\n    a2 = 1/np.sqrt(3)\n\n    \n    # The initialize function takes a list of amplitudes for the computational basis states\n    # Initialize the state to |ψ⟩ = a0|00⟩ + a1|10⟩ + a2|01⟩\n    initial_state = [a0, a2, a1, 0]  # Amplitudes for |00⟩, |01⟩, |10⟩, and |11⟩ respectively\n    qc.initialize(initial_state, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C3E3217165B", "submission_order": 2, "result": "UGE", "execution_time": "1460 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Define the amplitudes a0, a1, a2 (must be normalized)\n    a0 = 1/np.sqrt(3)\n    a1 = 1/np.sqrt(3)\n    a2 = 1/np.sqrt(3)\n\n    \n    # The initialize function takes a list of amplitudes for the computational basis states\n    # Initialize the state to |ψ⟩ = a0|00⟩ + a1|10⟩ + a2|01⟩\n    initial_state = [a0, a2, a1, 0]  # Amplitudes for |00⟩, |01⟩, |10⟩, and |11⟩ respectively\n    qc.initialize(initial_state, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C3E3217165B", "submission_order": 3, "result": "WA", "execution_time": "1654 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Start in the |00⟩ state (the default state)\n    \n    # Step 1: Apply Ry gate to qubit 0 to create a superposition\n    theta = 2 * np.arcsin(1/np.sqrt(3))  # Rotation angle to get the correct amplitude\n    qc.ry(theta, 0)\n    \n    # Step 2: Apply an X gate to qubit 1 controlled on qubit 0 to ensure superposition of |00⟩ and |10⟩\n    qc.cx(0, 1)\n\n    # Step 3: Apply Ry gate to qubit 1 to create the correct amplitude for |01⟩\n    qc.ry(theta, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C3E3217165B", "submission_order": 4, "result": "WA", "execution_time": "1595 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Start in the |00⟩ state (the default state)\n    qc.h(0)\n    # Step 1: Apply Ry gate to qubit 0 to create a superposition\n    theta = 2 * np.arcsin(1/np.sqrt(3))  # Rotation angle to get the correct amplitude\n    qc.ry(theta, 0)\n    \n    # Step 2: Apply an X gate to qubit 1 controlled on qubit 0 to ensure superposition of |00⟩ and |10⟩\n    qc.cx(0, 1)\n\n    # Step 3: Apply Ry gate to qubit 1 to create the correct amplitude for |01⟩\n    qc.ry(theta, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C3E3217165B", "submission_order": 5, "result": "WA", "execution_time": "1607 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Start in the |00⟩ state (default)\n    \n    # Step 2: Apply an H gate to qubit 0 to create superposition (|0⟩ + |1⟩)/sqrt(2)\n    qc.h(0)\n    \n    # Step 3: Apply an Ry gate to qubit 1 to adjust its amplitude \n    theta = 2 * np.arccos(1/np.sqrt(3))  # Angle to rotate to match the 1/sqrt(3) amplitude\n    qc.ry(theta, 1)\n    \n    # Step 4: Apply a CNOT gate to entangle qubit 0 with qubit 1\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C3E3217165B", "submission_order": 6, "result": "WA", "execution_time": "1619 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Start in the |00⟩ state (default)\n    \n    # Step 2: Apply an H gate to qubit 0 to create superposition (|0⟩ + |1⟩)/sqrt(2)\n    qc.h(0)\n    \n    # Step 3: Apply an Ry gate to qubit 1 to adjust its amplitude \n    theta = 2 * np.arcsin(1/np.sqrt(3))  # Angle to rotate to match the 1/sqrt(3) amplitude\n    qc.ry(theta, 1)\n    \n    # Step 4: Apply a CNOT gate to entangle qubit 0 with qubit 1\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1C5C8BCE0772", "submission_order": 1, "result": "AC", "execution_time": "1130 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1D2A5D965405", "submission_order": 1, "result": "WA", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1D2A5D965405", "submission_order": 2, "result": "AC", "execution_time": "919 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1DAC339CF76B", "submission_order": 1, "result": "AC", "execution_time": "1487 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1) \n    qc.ch(1,0)\n    qc.cx(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1E150DC634F0", "submission_order": 1, "result": "AC", "execution_time": "946 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1E7DC75E9568", "submission_order": 1, "result": "WA", "execution_time": "902 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1E7DC75E9568", "submission_order": 2, "result": "WA", "execution_time": "1521 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1E7DC75E9568", "submission_order": 3, "result": "RE", "execution_time": "772 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n# 初期状態 |ψ⟩ を作成\ninitial_state = [1/2, 1/4, 1/4, 0]  # a₀|00⟩ + a₁|10⟩ + a₂|01⟩ + 0|11⟩\ninitializer = Initialize(initial_state)\ninitializer.label = \"init\"\n\n# 回路に初期化ゲートを適用\nqc.append(initializer, qr)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1EBA8B33BB36", "submission_order": 1, "result": "WA", "execution_time": "914 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(range(2))\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1EBA8B33BB36", "submission_order": 2, "result": "WA", "execution_time": "1017 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1EBA8B33BB36", "submission_order": 3, "result": "WA", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1EBA8B33BB36", "submission_order": 4, "result": "WA", "execution_time": "820 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1EBA8B33BB36", "submission_order": 5, "result": "WA", "execution_time": "974 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1F1086472775", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit import QuantumCircuit\nfrom qiskit.quantum_info import DensityMatrix\nfrom qiskit.visualization import plot_state_city\nfrom qiskit import Aer, execute\nimport numpy as np\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    # 00 10\n    # 00 01 11\n    qc.cu(np.pi/4,0,0,0,0,1)\n    qc.cx(1,0)\n    #qc.rx(np.pi/ 2,0)\n    \n    # Write your code here:\n\n    return qc\n\ndef simulate(qc: QuantumCircuit):\n    simulator = Aer.get_backend(\"statevector_simulator\")\n    statevector = execute(qc, simulator).result().get_statevector(qc)\n    print(statevector)\n\nsimulate(solve())\n'''"}
{"problem": "QPC001_A4", "user": "A1F1086472775", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit import QuantumCircuit\nfrom qiskit.quantum_info import DensityMatrix\nfrom qiskit.visualization import plot_state_city\n\nfrom math import py\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    # 00 10\n    # 00 01 11\n    qc.cu(pi/4,0,0,0,0,1)\n    qc.cx(1,0)\n    #qc.rx(np.pi/ 2,0)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1F1086472775", "submission_order": 3, "result": "AC", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom math import pi\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    # 00 10\n    # 00 01 11\n    qc.cu(pi/4,0,0,0,0,1)\n    qc.cx(1,0)\n    #qc.rx(np.pi/ 2,0)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A1F78CADF487C", "submission_order": 1, "result": "AC", "execution_time": "894 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0,1)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A204B1E935E3B", "submission_order": 1, "result": "WA", "execution_time": "1058 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A204B1E935E3B", "submission_order": 2, "result": "WA", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A204B1E935E3B", "submission_order": 3, "result": "WA", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1, 0)\n    qc.h(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A204B1E935E3B", "submission_order": 4, "result": "WA", "execution_time": "829 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1, 0)\n    qc.h(1)\n    qc.h(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A204B1E935E3B", "submission_order": 5, "result": "WA", "execution_time": "1032 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(0, 1)\n    qc.h(1)\n    qc.h(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A205E933AA284", "submission_order": 1, "result": "AC", "execution_time": "2155 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A21F576A4C3B0", "submission_order": 1, "result": "AC", "execution_time": "949 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A220880CDE4A5", "submission_order": 1, "result": "WA", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(2):\n        qc.h(i)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A220880CDE4A5", "submission_order": 2, "result": "WA", "execution_time": "1567 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A220880CDE4A5", "submission_order": 3, "result": "WA", "execution_time": "838 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = math.acos(math.sqrt(2/3))\n    if theta < 0:\n        theta = theta*-1\n    qc.ry(theta,1)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A220880CDE4A5", "submission_order": 4, "result": "WA", "execution_time": "829 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = 2*math.acos(math.sqrt(2/3))\n    if theta < 0:\n        theta = theta*-1\n    qc.ry(theta,1)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A220880CDE4A5", "submission_order": 5, "result": "WA", "execution_time": "882 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = 2*math.acos(math.sqrt(2/3))\n    if theta < 0:\n        theta = theta*-1\n    qc.ry(theta,0)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A220880CDE4A5", "submission_order": 6, "result": "AC", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = 2*math.acos(math.sqrt(2/3))\n    if theta < 0:\n        theta = theta*-1\n    qc.ry(theta,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A22B6BC66469A", "submission_order": 1, "result": "AC", "execution_time": "1177 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A246F83369F61", "submission_order": 1, "result": "AC", "execution_time": "1458 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2473294515B5", "submission_order": 1, "result": "RE", "execution_time": "775 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.H(0)\n    qc.swap(0, 1)\n    qc.H(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2473294515B5", "submission_order": 2, "result": "RE", "execution_time": "819 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.H(0)\n    qc.CX(0,1)\n    qc.CX(1,0)\n    qc.CX(0,1)\n    qc.H(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2473294515B5", "submission_order": 3, "result": "WA", "execution_time": "989 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2473294515B5", "submission_order": 4, "result": "WA", "execution_time": "934 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(0,1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2473294515B5", "submission_order": 5, "result": "WA", "execution_time": "958 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(0,1)\n    qc.h(0)\n    print(qc)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25B9521B59CA", "submission_order": 1, "result": "AC", "execution_time": "1353 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 1, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 2, "result": "WA", "execution_time": "1402 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 3, "result": "RE", "execution_time": "808 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.CHgate(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 4, "result": "RE", "execution_time": "756 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.CHGate(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 5, "result": "WA", "execution_time": "821 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 6, "result": "RE", "execution_time": "752 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.c(1, 0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 7, "result": "WA", "execution_time": "877 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 8, "result": "WA", "execution_time": "808 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 9, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A25E2C713EE3D", "submission_order": 10, "result": "AC", "execution_time": "1094 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A28B6A15E5E70", "submission_order": 1, "result": "RE", "execution_time": "1754 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cz(0, 1)\n    qc.p(a0.real, 0)\n    qc.p(a1.real, 1)\n    phi0, phi1, phi2 = [a0.imag, a1.imag, a2.imag]\n    qc.ry(2*phi0, 0)\n    qc.ry(2*phi1, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A28B6A15E5E70", "submission_order": 2, "result": "RE", "execution_time": "1230 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cz(0, 1)\n    a0 = complex(np.random.rand(), np.random.rand())\n    a1 = complex(np.random.rand(), np.random.rand())\n    a2 = complex(np.random.rand(), np.random.rand()) \n    norm = np.sqrt(abs(a0)**2 + abs(a1)**2 + abs(a2)**2)\n    a0 /= norm\n    a1 /= norm\n    a2 /= norm\n    init_gate = Initialize([a0, a1, a2, 0])\n    qc.append(init_gate, [0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A28B6A15E5E70", "submission_order": 3, "result": "RE", "execution_time": "797 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(theta, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A28B6A15E5E70", "submission_order": 4, "result": "RE", "execution_time": "1738 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(theta_a1, 1)\n    qc.cx(1, 0)\n    qc.cry(theta_a2, 1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A28B6A15E5E70", "submission_order": 5, "result": "WA", "execution_time": "965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A28B6A15E5E70", "submission_order": 6, "result": "WA", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    some_angle_1 = 2 * math.acos(1)\n    qc.rx(some_angle_1, 0)\n    some_angle_2 = 2 * math.acos(1)\n    qc.rx(some_angle_2, 1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2BEC952BED8B", "submission_order": 1, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2BEC952BED8B", "submission_order": 2, "result": "AC", "execution_time": "818 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2E15180773F6", "submission_order": 1, "result": "WA", "execution_time": "816 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2E15180773F6", "submission_order": 2, "result": "AC", "execution_time": "799 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2F5EBAC65AE2", "submission_order": 1, "result": "WA", "execution_time": "814 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2F5EBAC65AE2", "submission_order": 2, "result": "WA", "execution_time": "804 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2F5EBAC65AE2", "submission_order": 3, "result": "AC", "execution_time": "1392 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    \n    prob_amp = math.sqrt(1 / 3)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 0, 1)\n    qc.cx(1, 0)\n\n    prob_amp = math.sqrt(1 / 2)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 1, 0)\n    \n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2FFCDA029D88", "submission_order": 1, "result": "WA", "execution_time": "810 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2FFCDA029D88", "submission_order": 2, "result": "WA", "execution_time": "933 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2FFCDA029D88", "submission_order": 3, "result": "WA", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2FFCDA029D88", "submission_order": 4, "result": "WA", "execution_time": "852 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2FFCDA029D88", "submission_order": 5, "result": "WA", "execution_time": "1447 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A2FFCDA029D88", "submission_order": 6, "result": "AC", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.2310,0)\n    qc.ry(0.785398,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-0.785398,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A308D75EB2A7C", "submission_order": 1, "result": "RE", "execution_time": "793 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0)\n    qc.x(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A308D75EB2A7C", "submission_order": 2, "result": "WA", "execution_time": "860 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A308D75EB2A7C", "submission_order": 3, "result": "WA", "execution_time": "896 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A308D75EB2A7C", "submission_order": 4, "result": "WA", "execution_time": "832 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A308D75EB2A7C", "submission_order": 5, "result": "WA", "execution_time": "849 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A308D75EB2A7C", "submission_order": 6, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 1, "result": "WA", "execution_time": "900 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 2, "result": "WA", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 3, "result": "WA", "execution_time": "985 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a = 1/3\n\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0, 1)\n\n    qc.rz(2*a, 1)\n\n    qc.cx(0, 1)\n\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 4, "result": "RE", "execution_time": "1641 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    # 制御ユニタリゲート（CU1）を適用\n    theta = 2 * math.acos(1/math.sqrt(3))  # 回転角度を計算\n    qc.cu1(theta, 0, 1)  # 制御ビット：1番目のビット、ターゲットビット：2番目のビット\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 5, "result": "RE", "execution_time": "758 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    # 制御ユニタリゲート（CU1）を適用\n    theta = 2 * math.acos(1/mat.sqrt(3))  # 回転角度を計算\n    qc.CU1Gate(theta, 0, 1)  # 制御ビット：1番目のビット、ターゲットビット：2番目のビット\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 6, "result": "RE", "execution_time": "791 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = 0.6\n    a1 = -0.4\n    a2 = 0.8\n\n    qc.ry(2 * math.asin(math.sqrt(a0)), 0)\n\n\n    qc.ry(2 * math.asin(math.sqrt(a1)), 1)\n\n\n    qc.ry(2 * math.asin(math.sqrt(a2)), 0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 7, "result": "RE", "execution_time": "811 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = 0.6\n    a1 = -0.4\n    a2 = 0.8\n\n    qc.ry(2 * math.asin(math.sqrt(a0)), 0)\n\n\n    qc.ry(2 * math.asin(math.sqrt(a1)), 1)\n\n\n    qc.ry(2 * math.asin(math.sqrt(a2)), 0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 8, "result": "WA", "execution_time": "837 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 9, "result": "WA", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 10, "result": "WA", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 11, "result": "WA", "execution_time": "1384 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0,1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 12, "result": "RE", "execution_time": "760 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.u1(2 * 1.047, 0)  # 1.047は適当な位相（2π/3）\n    qc.u1(4 * 1.047, 1)\n# 回路作成して測定\nqc =   circuit_bin4(theta0, theta1, theta2)  \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 13, "result": "RE", "execution_time": "1094 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.U1Gate(2 * 1.047, 0)  # 1.047は適当な位相（2π/3）\n    qc.U1Gate(4 * 1.047, 1)\n# 回路作成して測定\nqc =   circuit_bin4(theta0, theta1, theta2)  \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 14, "result": "WA", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.p(2 * 1.047, 0)  # 1.047は適当な位相（2π/3）\n    qc.p(4 * 1.047, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 15, "result": "WA", "execution_time": "834 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)  # Xゲートを量子ビット0に適用\n    qc.h(0)  # アダマールゲートを量子ビット0に適用\n    qc.cx(0, 1) \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 16, "result": "WA", "execution_time": "911 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    # CNOTゲートを適用\n    qc.x(0)\n    qc.x(1)\n    qc.cx(0, 1)\n\n   \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 17, "result": "RE", "execution_time": "1898 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CU3Gate\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    # 制御回転ゲートを使用して目的の状態 |ψ⟩ を作成\n    a0 = 0.5  # 任意の係数 a0\n    a1 = 0.3  # 任意の係数 a1\n    a2 = 0.8  # 任意の係数 a2\n\n    # 制御回転ゲートを使用して目的の状態 |ψ⟩ を作成\n    qc.CU3Gate(2*a0, 0, 0, 0, 1)  # 制御ビット：量子ビット0、標的ビット：量子ビット1\n    qc.CU3Gate(2*a1, 0, 0, 1, 0)  # 制御ビット：量子ビット1、標的ビット：量子ビット0\n    qc.CU3Gate(2*a2, 0, 0, 1, 1) \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A30A088C98C52", "submission_order": 18, "result": "RE", "execution_time": "739 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CU3Gate\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    # 制御回転ゲートを使用して目的の状態 |ψ⟩ を作成\n    a0 = 0.5  # 任意の係数 a0\n    a1 = 0.3  # 任意の係数 a1\n    a2 = 0.8  # 任意の係数 a2\n\n    # 制御回転ゲートを使用して目的の状態 |ψ⟩ を作成\n    qc.CU3Gate(2*a0, 0, 0, 0)  # 制御ビット：量子ビット0、標的ビット：量子ビット1\n    qc.CU3Gate(2*a1, 0, 0, 1)  # 制御ビット：量子ビット1、標的ビット：量子ビット0\n    qc.CU3Gate(2*a2, 0, 0, 1) \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3222815BDA34", "submission_order": 1, "result": "WA", "execution_time": "1471 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-math.pi / 4, 1)\n    qc.cz(0, 1)\n    qc.ry(math.pi / 4, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3222815BDA34", "submission_order": 2, "result": "AC", "execution_time": "831 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-math.pi / 4, 1)\n    qc.cz(0, 1)\n    qc.ry(math.pi / 4, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3226AFB3BE17", "submission_order": 1, "result": "WA", "execution_time": "1437 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(range(2))\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3226AFB3BE17", "submission_order": 2, "result": "AC", "execution_time": "1662 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A33A05867CD30", "submission_order": 1, "result": "AC", "execution_time": "1749 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) #|a> = 1/2^1/2(|00> + |10>)\n    qc.ch(0,1) # |00> + |10> + |11>\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A348936BF7C78", "submission_order": 1, "result": "AC", "execution_time": "1670 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1/math.sqrt(3))*2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 1, "result": "WA", "execution_time": "847 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 2, "result": "WA", "execution_time": "948 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 3, "result": "TLE", "execution_time": "2000 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 4, "result": "WA", "execution_time": "796 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 5, "result": "WA", "execution_time": "1854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 6, "result": "WA", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 7, "result": "WA", "execution_time": "1361 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 8, "result": "WA", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 9, "result": "WA", "execution_time": "818 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 10, "result": "WA", "execution_time": "833 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 11, "result": "WA", "execution_time": "932 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 12, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 13, "result": "WA", "execution_time": "911 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 14, "result": "RE", "execution_time": "840 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.z(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 15, "result": "WA", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 16, "result": "WA", "execution_time": "1130 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 17, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 18, "result": "WA", "execution_time": "938 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 19, "result": "WA", "execution_time": "1107 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 20, "result": "WA", "execution_time": "923 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 21, "result": "WA", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 22, "result": "WA", "execution_time": "821 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 23, "result": "WA", "execution_time": "897 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.x(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 24, "result": "WA", "execution_time": "924 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 25, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 26, "result": "WA", "execution_time": "918 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 27, "result": "WA", "execution_time": "835 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 28, "result": "RE", "execution_time": "759 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cz(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 29, "result": "WA", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 30, "result": "WA", "execution_time": "932 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cz(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 31, "result": "WA", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 32, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 33, "result": "WA", "execution_time": "820 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 34, "result": "WA", "execution_time": "851 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cz(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 35, "result": "WA", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cz(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 36, "result": "WA", "execution_time": "1875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.h(1)\n    qc.cz(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 37, "result": "WA", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(1)\n    qc.cz(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 38, "result": "WA", "execution_time": "1671 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(1)\n    qc.cz(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 39, "result": "WA", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    qc.h(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 40, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 41, "result": "WA", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.z(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 42, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.z(1)\n    qc.h(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 43, "result": "WA", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cz(1, 0)\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 44, "result": "WA", "execution_time": "1350 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cz(1, 0)\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A350F571F0AE2", "submission_order": 45, "result": "WA", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cz(1, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A35FFE24FC7AC", "submission_order": 1, "result": "WA", "execution_time": "2063 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.x(1)\n    qc.cx(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A35FFE24FC7AC", "submission_order": 2, "result": "WA", "execution_time": "2227 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A35FFE24FC7AC", "submission_order": 3, "result": "WA", "execution_time": "1982 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ry(0.1,0)\n    qc.cx(0,1)\n    qc.ry(-0.1,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A35FFE24FC7AC", "submission_order": 4, "result": "AC", "execution_time": "1905 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A37713AF1B262", "submission_order": 1, "result": "AC", "execution_time": "970 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef one2one(bit_org: int, bit: int, n_qubits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    b = 1\n    bit_dif = bit_org ^ bit\n    for i in range(n_qubits):\n        if (bit_dif&b) > 0:\n            qc.x(i)\n        b *= 2\n    return qc\n\ndef one2two(bit_org: int, bit1: int, bit2: int, n_qubits: int) -> QuantumCircuit:\n    if bit1==bit2:\n        return one2one(bit_org, bit1, n_qubits)\n    qc = QuantumCircuit(n_qubits)\n    bit1_dif = bit_org ^ bit1\n    bit2_dif = bit_org ^ bit2\n    dif_common = bit1_dif & bit2_dif\n    dif_dif = bit1_dif ^ bit2_dif\n    if dif_common == bit2_dif:\n        bit1, bit2 = bit2, bit1\n        bit1_dif, bit2_dif = bit2_dif, bit1_dif\n    b = 1\n    bit2_dif_last = -1\n    for i in range(n_qubits):\n        if (dif_common&b)>0:\n            qc.x(i)\n        if ((dif_dif&bit2_dif)&b)>0:\n            bit2_dif_last = i\n        b *= 2\n    if (1<<bit2_dif_last)&bit_org > 0:\n        qc.x(bit2_dif_last)\n    qc.h(bit2_dif_last)\n    if (1<<bit2_dif_last)&bit_org > 0:\n        qc.x(bit2_dif_last)\n    b = 1\n    for i in range(n_qubits):\n        if ((dif_dif&bit1_dif)&b)>0:\n            qc.cx(bit2_dif_last, i)\n        b *= 2\n    qc.x(bit2_dif_last)\n    b = 1\n    for i in range(n_qubits):\n        if ((dif_dif&bit2_dif)&b)>0 and i != bit2_dif_last:\n            qc.cx(bit2_dif_last, i)\n        b *= 2\n    if (1<<bit2_dif_last)&bit_org > 0:\n        qc.x(bit2_dif_last)\n    return qc\n\ndef one2three(bit_org: int, bit1: int, bit2: int, bit3: int, n_qubits: int) -> QuantumCircuit:\n    if bit1 == bit2 == bit3:\n        return one2one(bit_org, bit1, n_qubits)\n    \n    qc = QuantumCircuit(n_qubits)\n    b = 1\n    for i in range(n_qubits):\n        if (b&bit_org) > 0:\n            qc.x(i)\n        b *= 2\n\n    b = 1\n    for i in range(n_qubits):\n        if not ((b&bit1) == (b&bit2) == (b&bit3)):\n            if (b&bit1) == (b&bit2):\n                bit1, bit3 = bit3, bit1\n            elif (b&bit1) == (b&bit3):\n                bit1, bit2 = bit2, bit1\n            bit1ctrl = i\n            bit1ctrlsgn = ((bit1&b) > 0)\n            if bit1ctrlsgn:\n                qc.ry(2*math.acos((2/3)**0.5), bit1ctrl)            \n            else:\n                qc.ry(2*math.acos((1/3)**0.5), bit1ctrl)            \n            break\n        b *= 2\n\n    if not bit1ctrlsgn:\n        qc.x(bit1ctrl)    \n    b = 1\n    for i in range(n_qubits):\n        if (b&bit1) > 0 and i != bit1ctrl:\n            qc.cx(bit1ctrl, i)\n        b *= 2\n    if not bit1ctrlsgn:\n        qc.x(bit1ctrl)\n\n    if bit1ctrlsgn:\n        qc.x(bit1ctrl)\n    if bit2 == bit3:\n        b = 1\n        for i in range(n_qubits):\n            if (bit2&b) > 0 and i != bit1ctrl:\n                qc.cx(bit1ctrl, i)\n            b *= 2\n    else:\n        b = 1\n        for i in range(n_qubits):\n            if (bit2&b) != (bit3&b) and i != bit1ctrl:\n                qc.ch(bit1ctrl, i)\n                if (bit2&b) == 0:\n                    bit2, bit3 = bit3, bit2\n                bit2ctrl = i\n                break\n            b *= 2\n        b = 1\n        for i in range(n_qubits):\n            if (bit2&b) > 0 and i != bit2ctrl and i != bit1ctrl:\n                qc.ccx(bit1ctrl, bit2ctrl, i)\n            b *= 2\n        qc.cx(bit1ctrl, bit2ctrl)\n        b = 1\n        for i in range(n_qubits):\n            if (bit3&b) > 0 and i!=bit2ctrl and i != bit1ctrl:\n                qc.ccx(bit1ctrl, bit2ctrl, i)\n            b *= 2\n        qc.cx(bit1ctrl, bit2ctrl)\n    if bit1ctrlsgn:\n        qc.x(bit1ctrl)\n    return qc\ndef solve() -> QuantumCircuit:\n    qc = one2three(0, 0, 1, 2, 2)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 1, "result": "RE", "execution_time": "784 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.231,0)\n    qc.ry(3.14/4,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-3.14/4,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 2, "result": "RE", "execution_time": "760 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.231,0)\n    qc.ry(math.pi/4,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-math.pi/4,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 3, "result": "RE", "execution_time": "823 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 0.15\n    phi = 0.0\n    λ = math.pi\n    #qc.h(0)\n    qc.u(theta, phi, λ,0)\n    qc.u(theta, phi, λ,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 4, "result": "RE", "execution_time": "762 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.pi/12\n    phi = -math.pi\n    λ = math.pi/12\n    #qc.h(0)\n    qc.u(theta, phi, λ,0)\n    qc.u(theta, phi, λ,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 5, "result": "RE", "execution_time": "1193 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(2.9, 0, 0, 0)  # 0番目の量子ビットにU3ゲートを適用\n    qc.u(1.46, 0, 0, 1)  # 1番目の量子ビットにU3ゲートを適用\n    qc.cx(0,1)\n    qc.u(-1.21, 0, 0, 1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 6, "result": "RE", "execution_time": "755 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(2.03, 0, 0, 0)   \n    qc.u(1.46, 0, 0, 1)  \n    qc.cx(1,0)\n    qc.u(-1.11, 0, 0, 0)\n    qc.cx(1,0)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 7, "result": "RE", "execution_time": "809 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.append(h_c, [0,1])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 8, "result": "RE", "execution_time": "806 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    h_c = HGate().control(1)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.append(h_c, [0,1])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 9, "result": "RE", "execution_time": "753 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    control_H = HGate().control(1)\n    qc.h(0)\n    qc.x(0)\n    qc.append(control_H, [0,1])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 10, "result": "RE", "execution_time": "881 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    control_H = HGate().control(1)\n    qc.h(0)\n    qc.x(0)\n    qc.append(control_H, [0,1])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 11, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    control_H = HGate().control(1)\n    qc.h(0)\n    qc.x(0)\n    qc.append(control_H, [0,1])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 12, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    control_H = HGate().control(1)\n    qc.h(0)\n    qc.x(0)\n    qc.append(control_H, [0,1])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38385612D1C7", "submission_order": 13, "result": "AC", "execution_time": "1532 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    control_H = HGate().control(1)\n    qc.h(0)\n    qc.x(0)\n    qc.append(control_H, [0,1])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3887EA551A63", "submission_order": 1, "result": "RE", "execution_time": "903 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc,h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3887EA551A63", "submission_order": 2, "result": "RE", "execution_time": "795 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    with qc.if_test((0, 0)):\n        qc.h(1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3887EA551A63", "submission_order": 3, "result": "RE", "execution_time": "836 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    with qc.if_test((0, 0)):\n        qc.h(1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3887EA551A63", "submission_order": 4, "result": "WA", "execution_time": "1605 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    \n\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3887EA551A63", "submission_order": 5, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.h(0)\n    qc.ch(1,0)\n      \n\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A38E157AB4E10", "submission_order": 1, "result": "AC", "execution_time": "1850 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    qc.h(1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3903AF71F50E", "submission_order": 1, "result": "WA", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3A05476BC363", "submission_order": 1, "result": "AC", "execution_time": "854 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3A4989D54C48", "submission_order": 1, "result": "WA", "execution_time": "937 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3A4989D54C48", "submission_order": 2, "result": "RE", "execution_time": "811 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3A4989D54C48", "submission_order": 3, "result": "WA", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3A4989D54C48", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3A4989D54C48", "submission_order": 5, "result": "AC", "execution_time": "897 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3C3AD5638A3C", "submission_order": 1, "result": "WA", "execution_time": "1483 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3C3AD5638A3C", "submission_order": 2, "result": "AC", "execution_time": "1495 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3C95A518CFE8", "submission_order": 1, "result": "AC", "execution_time": "865 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CD9DE3A50CA", "submission_order": 1, "result": "AC", "execution_time": "1973 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 1, "result": "WA", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 2, "result": "WA", "execution_time": "1447 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cz(0,1)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 3, "result": "WA", "execution_time": "1540 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 4, "result": "RE", "execution_time": "1783 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1,0)\n    qc.(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 5, "result": "RE", "execution_time": "741 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1,0)\n    qc.(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 6, "result": "WA", "execution_time": "1920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 7, "result": "WA", "execution_time": "1536 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 8, "result": "WA", "execution_time": "1965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 9, "result": "WA", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 10, "result": "WA", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cz(0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A3CF92CE9FD80", "submission_order": 11, "result": "WA", "execution_time": "961 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A40A9A9E24F30", "submission_order": 1, "result": "AC", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(range(2))\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(range(2))\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A426D23809C30", "submission_order": 1, "result": "WA", "execution_time": "934 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A426D23809C30", "submission_order": 2, "result": "WA", "execution_time": "828 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A426D23809C30", "submission_order": 3, "result": "AC", "execution_time": "809 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A42A649004315", "submission_order": 1, "result": "AC", "execution_time": "1568 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4362C2E050E3", "submission_order": 1, "result": "WA", "execution_time": "920 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4362C2E050E3", "submission_order": 2, "result": "AC", "execution_time": "1030 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A43B258CB8C46", "submission_order": 1, "result": "AC", "execution_time": "1860 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A43CF3CEBF363", "submission_order": 1, "result": "RE", "execution_time": "1767 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.rx(0, 2 * pi/3)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A43CF3CEBF363", "submission_order": 2, "result": "AC", "execution_time": "2079 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.rx(2 * pi/3, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A44EDA30F1F43", "submission_order": 1, "result": "AC", "execution_time": "1454 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n\n    prob_amp = math.sqrt(1 / 3)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 0, 1)\n    qc.cx(1, 0)\n\n    prob_amp = math.sqrt(1 / 2)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 1, 0)\n\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A450BBE3FF161", "submission_order": 1, "result": "QLE", "execution_time": "751 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    # Toffoliゲートを適用（00、01、10の状態には影響なし、11の状態だけで補助ビットを反転）\n    qc.ccx(0, 1, 2)\n\n    # 必要に応じて補助ビットに対して追加の操作を行う\n    # 例: 補助ビットにZゲートを適用\n    qc.cx(2,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A450BBE3FF161", "submission_order": 2, "result": "AC", "execution_time": "975 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A450D1F435477", "submission_order": 1, "result": "WA", "execution_time": "981 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A450D1F435477", "submission_order": 2, "result": "AC", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A45352F956D47", "submission_order": 1, "result": "AC", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A45EBD39E1A15", "submission_order": 1, "result": "RE", "execution_time": "1439 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ccx(0,1,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A46478803703A", "submission_order": 1, "result": "AC", "execution_time": "1558 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A46B4B79E3468", "submission_order": 1, "result": "WA", "execution_time": "1435 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A46B4B79E3468", "submission_order": 2, "result": "WA", "execution_time": "1419 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A46B4B79E3468", "submission_order": 3, "result": "WA", "execution_time": "1433 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, sqrt\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Define the coefficients\n    a0 = 1/sqrt(3)\n    a1 = 1/sqrt(3)\n    a2 = 1/sqrt(3)\n\n    # Normalize the coefficients (if they aren't normalized already)\n    norm = sqrt(abs(a0)**2 + abs(a1)**2 + abs(a2)**2)\n    a0 /= norm\n    a1 /= norm\n    a2 /= norm\n\n    # Create a quantum circuit with 2 qubits\n    qc = QuantumCircuit(2)\n\n    # Step 1: Apply a rotation on qubit 0 to create the superposition for a0 and the sum of a1 + a2\n    theta_1 = 2 * np.arccos(a0)\n    qc.ry(theta_1, 0)\n\n    # Step 2: Apply a controlled rotation on qubit 1 based on qubit 0 to differentiate between a1 and a2\n    theta_2 = 2 * np.arccos(a2 / sqrt(a1**2 + a2**2))\n    qc.cry(theta_2, 0, 1)\n\n    # Step 3: Apply an X gate on qubit 0 to swap the states for a1 and a2\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A46B4B79E3468", "submission_order": 4, "result": "AC", "execution_time": "1381 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A46B5C00E80A2", "submission_order": 1, "result": "AC", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A470B706E559D", "submission_order": 1, "result": "WA", "execution_time": "2068 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.ch(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A470B706E559D", "submission_order": 2, "result": "AC", "execution_time": "1797 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4BB3944A01D2", "submission_order": 1, "result": "AC", "execution_time": "849 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4D68D50A97FE", "submission_order": 1, "result": "AC", "execution_time": "1413 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4E127C045851", "submission_order": 1, "result": "AC", "execution_time": "1203 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4F9BED8093E8", "submission_order": 1, "result": "RE", "execution_time": "1916 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    theta2 = (np.pi/4)\n\n    qc.ry(theta=theta1, qubit=0)\n    qc.ry(theta=theta2, qubit=1)\n    qc.cx(control_qubit=0, target_qubit=1)\n    qc.ry(theta=-theta2, qubit=1)\n    qc.x(qubit=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4F9BED8093E8", "submission_order": 2, "result": "AC", "execution_time": "1858 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    theta2 = (np.pi/4)\n\n    qc.ry(theta=theta1, qubit=0)\n    qc.ry(theta=theta2, qubit=1)\n    qc.cx(control_qubit=0, target_qubit=1)\n    qc.ry(theta=-theta2, qubit=1)\n    qc.x(qubit=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4FC0AAA43890", "submission_order": 1, "result": "AC", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A4FE41A8E630C", "submission_order": 1, "result": "AC", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A505E31A33C71", "submission_order": 1, "result": "WA", "execution_time": "1343 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A505E31A33C71", "submission_order": 2, "result": "AC", "execution_time": "1349 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 1, "result": "WA", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 2, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 3, "result": "WA", "execution_time": "1868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 4, "result": "WA", "execution_time": "1707 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 5, "result": "WA", "execution_time": "925 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 6, "result": "WA", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 7, "result": "WA", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 8, "result": "WA", "execution_time": "904 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 9, "result": "WA", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 10, "result": "WA", "execution_time": "938 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 11, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.append(HGate().control(0), [1])\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 12, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.H(1).control(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 13, "result": "RE", "execution_time": "746 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.H(1).control(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 14, "result": "WA", "execution_time": "854 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5123B243D657", "submission_order": 15, "result": "AC", "execution_time": "892 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A51A6918C1BE7", "submission_order": 1, "result": "WA", "execution_time": "928 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A51A6918C1BE7", "submission_order": 2, "result": "WA", "execution_time": "1791 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A51A6918C1BE7", "submission_order": 3, "result": "WA", "execution_time": "806 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A51A6918C1BE7", "submission_order": 4, "result": "AC", "execution_time": "846 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A539354F76F87", "submission_order": 1, "result": "AC", "execution_time": "1408 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5529A8FFCC0E", "submission_order": 1, "result": "AC", "execution_time": "905 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\tqc.swap(0, 1)\n\tqc.h(0)\n\tqc.h(1)\n\tqc.ch(1, 0)\n\treturn qc\n'''"}
{"problem": "QPC001_A4", "user": "A55BAF0C3D228", "submission_order": 1, "result": "AC", "execution_time": "838 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55C5E8E89B96", "submission_order": 1, "result": "WA", "execution_time": "820 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55C5E8E89B96", "submission_order": 2, "result": "AC", "execution_time": "762 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 1, "result": "WA", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 2, "result": "WA", "execution_time": "842 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 3, "result": "WA", "execution_time": "848 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 4, "result": "RE", "execution_time": "799 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.crh(pi, 1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 5, "result": "RE", "execution_time": "823 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.crh(-pi/2,1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 6, "result": "RE", "execution_time": "758 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.crh(-pi/2,1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 7, "result": "WA", "execution_time": "814 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 8, "result": "WA", "execution_time": "885 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 9, "result": "WA", "execution_time": "826 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A55D895DF5B5C", "submission_order": 10, "result": "AC", "execution_time": "845 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5630B0EED3E4", "submission_order": 1, "result": "WA", "execution_time": "1434 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5630B0EED3E4", "submission_order": 2, "result": "AC", "execution_time": "1648 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A56F621A0F2A8", "submission_order": 1, "result": "AC", "execution_time": "901 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A573F3D42B8F9", "submission_order": 1, "result": "WA", "execution_time": "900 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A573F3D42B8F9", "submission_order": 2, "result": "RE", "execution_time": "833 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(1)\n    qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A573F3D42B8F9", "submission_order": 3, "result": "WA", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A573F3D42B8F9", "submission_order": 4, "result": "WA", "execution_time": "1416 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A573F3D42B8F9", "submission_order": 5, "result": "AC", "execution_time": "861 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5807BCB5EC51", "submission_order": 1, "result": "WA", "execution_time": "975 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5807BCB5EC51", "submission_order": 2, "result": "RE", "execution_time": "1452 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),1)\n\n    qc.x(1)\n\n    qc.ch(1,0)\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5807BCB5EC51", "submission_order": 3, "result": "AC", "execution_time": "1894 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),1)\n\n    qc.x(1)\n\n    qc.ch(1,0)\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A587527BDA250", "submission_order": 1, "result": "AC", "execution_time": "1888 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A58A4375F0280", "submission_order": 1, "result": "AC", "execution_time": "1665 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A58D912D00BAE", "submission_order": 1, "result": "WA", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(1)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A58D912D00BAE", "submission_order": 2, "result": "WA", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(1,0)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A58D912D00BAE", "submission_order": 3, "result": "WA", "execution_time": "833 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.x(1)\n    qc.cx(1,0)\n\n    qc.x(1)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A58D912D00BAE", "submission_order": 4, "result": "AC", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.x(1)\n    qc.ch(1,0)\n\n    qc.x(1)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5A2F3D342CDB", "submission_order": 1, "result": "AC", "execution_time": "895 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5C0C591C17B0", "submission_order": 1, "result": "WA", "execution_time": "892 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5DC3072354A5", "submission_order": 1, "result": "AC", "execution_time": "1341 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5F3CD0DF7116", "submission_order": 1, "result": "RE", "execution_time": "734 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # a_0, a_1, a_2 の値に基づいて計算する必要がある\n    a_0 = 1 / sqrt(3)\n    a_1 = 1 / sqrt(3)\n    a_2 = 1 / sqrt(3)\n\n    # 角度 theta と phi を計算（ここでは例として設定しますが、a_0, a_1, a_2 に基づいて計算する必要があります）\n    theta = 2 * acos(sqrt(a_0**2 + a_2**2))\n    phi = 2 * acos(a_0 / sqrt(a_0**2 + a_2**2))\n    \n    # 1番目の量子ビットにRYゲートを適用\n    qc.ry(theta, 0)\n    \n    # 1番目の量子ビットを制御量子ビットとして、2番目の量子ビットにCNOTゲートを適用\n    qc.cx(0, 1)\n    \n    # 2番目の量子ビットにRYゲートを適用\n    qc.ry(phi, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5F4A26C3B700", "submission_order": 1, "result": "AC", "execution_time": "916 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 1, "result": "WA", "execution_time": "1886 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 2, "result": "RE", "execution_time": "1764 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cy(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 3, "result": "WA", "execution_time": "1872 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 4, "result": "WA", "execution_time": "1868 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 5, "result": "RE", "execution_time": "1760 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.h(0)\n    qc.cx(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 6, "result": "WA", "execution_time": "1839 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.y(0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 7, "result": "RE", "execution_time": "1761 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cry(pi/2, 1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 8, "result": "RE", "execution_time": "1761 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cry(pi/2, 1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A5FEB8576EFE3", "submission_order": 9, "result": "AC", "execution_time": "1885 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cry(pi/2, 1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6198F002B294", "submission_order": 1, "result": "AC", "execution_time": "845 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A62DB2CDB941E", "submission_order": 1, "result": "AC", "execution_time": "904 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = math.asin(1.0 / math.sqrt(3.0))\n    qc.ry(2.0 * theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6379DE28893C", "submission_order": 1, "result": "WA", "execution_time": "1935 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A63C651AEFC89", "submission_order": 1, "result": "WA", "execution_time": "1980 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A63C651AEFC89", "submission_order": 2, "result": "AC", "execution_time": "1720 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A65B29D13356C", "submission_order": 1, "result": "RE", "execution_time": "1340 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.h(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A65B29D13356C", "submission_order": 2, "result": "RE", "execution_time": "1373 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.cx(0,)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A65B29D13356C", "submission_order": 3, "result": "AC", "execution_time": "1346 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A65CBF53E5E38", "submission_order": 1, "result": "RE", "execution_time": "809 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.assign_parameters(a0,a1,a2,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A65CBF53E5E38", "submission_order": 2, "result": "RE", "execution_time": "854 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.assign_parameters(,,,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A65CBF53E5E38", "submission_order": 3, "result": "RE", "execution_time": "884 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.assign_parameters(,,,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A670D1413957D", "submission_order": 1, "result": "AC", "execution_time": "1704 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A67F2A8FCFE48", "submission_order": 1, "result": "AC", "execution_time": "1161 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6A550B4A7810", "submission_order": 1, "result": "WA", "execution_time": "815 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6A550B4A7810", "submission_order": 2, "result": "AC", "execution_time": "874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6ADBD4C53CAF", "submission_order": 1, "result": "WA", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6ADBD4C53CAF", "submission_order": 2, "result": "WA", "execution_time": "994 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6ADBD4C53CAF", "submission_order": 3, "result": "RE", "execution_time": "802 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(arccos(sqrt(2.0/3.0))*2.0, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6ADBD4C53CAF", "submission_order": 4, "result": "RE", "execution_time": "774 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.arccos(math.sqrt(2.0/3.0))*2.0, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6ADBD4C53CAF", "submission_order": 5, "result": "RE", "execution_time": "768 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.arccos(math.sqrt(2.0/3.0))*2.0, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6ADBD4C53CAF", "submission_order": 6, "result": "AC", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(2.0/3.0))*2.0, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6B2C381C4817", "submission_order": 1, "result": "WA", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6B2C381C4817", "submission_order": 2, "result": "AC", "execution_time": "1180 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6B5793587580", "submission_order": 1, "result": "AC", "execution_time": "824 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6D1DF00F5A7D", "submission_order": 1, "result": "WA", "execution_time": "1356 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6D1DF00F5A7D", "submission_order": 2, "result": "AC", "execution_time": "1401 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6DAE78AE2DE9", "submission_order": 1, "result": "AC", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(0)\n    qc.h(1)\n    qc.ch(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6E58763C8039", "submission_order": 1, "result": "AC", "execution_time": "866 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A6FBE253060F7", "submission_order": 1, "result": "AC", "execution_time": "1960 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A708602F63873", "submission_order": 1, "result": "WA", "execution_time": "811 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A708602F63873", "submission_order": 2, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A708602F63873", "submission_order": 3, "result": "WA", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A708602F63873", "submission_order": 4, "result": "RE", "execution_time": "1253 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A708602F63873", "submission_order": 5, "result": "RE", "execution_time": "1271 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ccx(0,1)\n    qc.h(2)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A708602F63873", "submission_order": 6, "result": "RE", "execution_time": "1015 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ccx(0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A708602F63873", "submission_order": 7, "result": "RE", "execution_time": "751 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ccx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A70BAADA4A7BA", "submission_order": 1, "result": "RE", "execution_time": "1526 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A70BAADA4A7BA", "submission_order": 2, "result": "AC", "execution_time": "1554 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cz(0,1)\n    qc.ch(0,1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A736EAC3F2C9F", "submission_order": 1, "result": "WA", "execution_time": "941 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(1,0)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A736EAC3F2C9F", "submission_order": 2, "result": "WA", "execution_time": "865 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A736EAC3F2C9F", "submission_order": 3, "result": "WA", "execution_time": "944 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n\nprint(solve())\n'''"}
{"problem": "QPC001_A4", "user": "A736EAC3F2C9F", "submission_order": 4, "result": "WA", "execution_time": "951 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A736EAC3F2C9F", "submission_order": 5, "result": "AC", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 1, "result": "WA", "execution_time": "1422 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.y(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 2, "result": "RE", "execution_time": "1291 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.rz(pi/3,0)\n    qc.rz(pi/2,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 3, "result": "WA", "execution_time": "1385 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.rz(pi/3,0)\n    qc.rz(pi/2,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 4, "result": "WA", "execution_time": "1401 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 5, "result": "WA", "execution_time": "1330 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 6, "result": "WA", "execution_time": "1463 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.rz(0,0)\n    qc.rz(0,1)\n    qc.rz(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 7, "result": "WA", "execution_time": "1551 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.rz(0,1)\n    qc.rz(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 8, "result": "WA", "execution_time": "1491 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.rz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 9, "result": "WA", "execution_time": "1614 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.rz(0,1)\n    qc.ry(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 10, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\nqc.h(1)\nqc.rz(pi/3, 0)  # 量子ビット0に位相を加える\nqc.rz(pi/2, 1)  # 量子ビット1に位相を加える\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 11, "result": "WA", "execution_time": "1501 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 12, "result": "RE", "execution_time": "1359 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A75440B74D33E", "submission_order": 13, "result": "AC", "execution_time": "1356 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A769FE9666704", "submission_order": 1, "result": "WA", "execution_time": "920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A769FE9666704", "submission_order": 2, "result": "AC", "execution_time": "819 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A76F7483FDD4A", "submission_order": 1, "result": "WA", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 2 * math.asin(math.sqrt(3)/3)\n    qc.ry(t, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A76F7483FDD4A", "submission_order": 2, "result": "WA", "execution_time": "859 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 2 * math.asin(math.sqrt(3)/3)\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A76F7483FDD4A", "submission_order": 3, "result": "WA", "execution_time": "1329 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 2 * math.asin(math.sqrt(3)/3)\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A76F7483FDD4A", "submission_order": 4, "result": "WA", "execution_time": "1488 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 2 * math.asin(math.sqrt(3)/3)\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A76F7483FDD4A", "submission_order": 5, "result": "AC", "execution_time": "830 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 2 * math.asin(math.sqrt(3)/3)\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7775B7BEEB86", "submission_order": 1, "result": "RE", "execution_time": "1379 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Define amplitudes a0, a1, a2; a3 = 0\n    norm = math.sqrt(3)\n    state = [1/norm, 1/norm, 1/norm, 0]  # [|00>, |01>, |10>, |11>]\n    qc.initialize(state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7775B7BEEB86", "submission_order": 2, "result": "AC", "execution_time": "1460 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A77B2A073FE71", "submission_order": 1, "result": "AC", "execution_time": "1803 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.ch(0,1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A79F43A33DF84", "submission_order": 1, "result": "AC", "execution_time": "1584 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7B5AEF551C73", "submission_order": 1, "result": "AC", "execution_time": "1428 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7BDBE2664E13", "submission_order": 1, "result": "AC", "execution_time": "1684 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) # |00>, |01>\n    qc.ch(0,1) # |00>, |01>, |11>\n    qc.x(0) # |01>, |00>, |10>\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7C1BCD21E8FC", "submission_order": 1, "result": "UGE", "execution_time": "915 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import SwapGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.append(SwapGate().power(1/2), [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7C1BCD21E8FC", "submission_order": 2, "result": "RE", "execution_time": "754 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import SwapGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.ry(math.pi / 2, 1)\n    qc.rz(math.pi / 16, 1)\n    qc.cx(0, 1)\n    qc.rz(math.pi / 8, 0)\n    qc.rz(-math.pi / 8, 1)\n    qc.cx(0, 1)\n    qc.rz(math.pi / 16, 1)\n    qc.ry(-math.pi / 2, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7C1BCD21E8FC", "submission_order": 3, "result": "RE", "execution_time": "1026 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.ry(math.pi / 2, 1)\n    qc.rz(math.pi / 16, 1)\n    qc.cx(0, 1)\n    qc.rz(math.pi / 8, 0)\n    qc.rz(-math.pi / 8, 1)\n    qc.cx(0, 1)\n    qc.rz(math.pi / 16, 1)\n    qc.ry(-math.pi / 2, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7C1BCD21E8FC", "submission_order": 4, "result": "AC", "execution_time": "929 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.ry(math.pi / 2, 1)\n    qc.rz(math.pi / 16, 1)\n    qc.cx(0, 1)\n    qc.rz(math.pi / 8, 0)\n    qc.rz(-math.pi / 8, 1)\n    qc.cx(0, 1)\n    qc.rz(math.pi / 16, 1)\n    qc.ry(-math.pi / 2, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7CF231E52225", "submission_order": 1, "result": "AC", "execution_time": "1398 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cry(3, 0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7D7B2FFF559B", "submission_order": 1, "result": "AC", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7E91974C6C66", "submission_order": 1, "result": "AC", "execution_time": "1990 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 1, "result": "WA", "execution_time": "879 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 2, "result": "WA", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 3, "result": "WA", "execution_time": "1168 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 4, "result": "TLE", "execution_time": "2000 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(1,0)\n    qc.cx(1,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 5, "result": "WA", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.h(0)\n    qc.cx(1,0)\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 6, "result": "RE", "execution_time": "1155 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,0)\n    qc.cx(1,0)\n    qc.cx(0,1)\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 7, "result": "WA", "execution_time": "1026 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 8, "result": "RE", "execution_time": "785 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.reset()\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 9, "result": "WA", "execution_time": "1370 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 10, "result": "WA", "execution_time": "824 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 11, "result": "WA", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.cx(1,0)\n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 12, "result": "WA", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.cx(0,1)\n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 13, "result": "WA", "execution_time": "1445 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 14, "result": "WA", "execution_time": "838 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.x(0)\n  \n\n    \n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 15, "result": "WA", "execution_time": "1241 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.x(1)\n  \n\n    \n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 16, "result": "RE", "execution_time": "884 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cU(1)\n  \n\n    \n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 17, "result": "RE", "execution_time": "1924 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cU(1,0)\n  \n\n    \n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 18, "result": "WA", "execution_time": "885 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n  \n\n    \n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 19, "result": "WA", "execution_time": "807 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n  \n\n    \n\n \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 20, "result": "WA", "execution_time": "929 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 21, "result": "WA", "execution_time": "862 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 22, "result": "WA", "execution_time": "906 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 23, "result": "WA", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 24, "result": "WA", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 25, "result": "WA", "execution_time": "811 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 26, "result": "WA", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(0)\n    qc.cx(1,0)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 27, "result": "WA", "execution_time": "887 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1,0)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 28, "result": "WA", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.h(1)\n    qc.cx(1,0)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 29, "result": "WA", "execution_time": "1756 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.h(0)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 30, "result": "WA", "execution_time": "997 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.h(0)\n    qc.cx(0,1)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 31, "result": "WA", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    \n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 32, "result": "RE", "execution_time": "766 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cswap(1,0,0)\n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 33, "result": "RE", "execution_time": "1585 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cswap(0,1,1)\n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 34, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 35, "result": "RE", "execution_time": "1123 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    a0, a1, a2 = 1, 1, 1\n    qc.initialize([a0, a1, a2, 0], [0, 1])\n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 36, "result": "WA", "execution_time": "1126 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.x(1)\n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 37, "result": "RE", "execution_time": "773 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # 任意の複素振幅を指定\n    a0 = 0.5  # 例として0.5を指定\n    a1 = 0.3  # 例として0.3を指定\n    a2 = 0.7  # 例として0.7を指定\n    \n    # 初期状態を作成\n    qc.h(0)  # アダマールゲートを使用して0番目の量子ビットに均等な重ね合わせを作成\n    qc.cx(0, 1)  # CNOTゲートを使用して0番目の量子ビットの情報を1番目の量子ビットにコピー\n    \n    # それぞれの振幅を適用\n    qc.u3(2*a0.real, 2*a0.imag, 0, 0)  # 0番目の量子ビットに対する振幅\n    qc.u3(2*a1.real, 2*a1.imag, 0, 1)  # 1番目の量子ビットに対する振幅\n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A7F505791B62F", "submission_order": 38, "result": "RE", "execution_time": "933 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # 任意の複素振幅を指定\n    a0 = 0.5  # 例として0.5を指定\n    a1 = 0.3  # 例として0.3を指定\n    a2 = 0.7  # 例として0.7を指定\n    \n    # 初期状態を作成\n    qc.h(0)  # アダマールゲートを使用して0番目の量子ビットに均等な重ね合わせを作成\n    qc.cx(0, 1)  # CNOTゲートを使用して0番目の量子ビットの情報を1番目の量子ビットにコピー\n    \n    # それぞれの振幅を適用\n    qc.u3(2*a0.real, 2*a0.imag, 0, 0)  # 0番目の量子ビットに対する振幅\n    qc.u3(2*a1.real, 2*a1.imag, 0, 1)  # 1番目の量子ビットに対する振幅\n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8032A2683C5C", "submission_order": 1, "result": "RE", "execution_time": "1703 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(sqrt(1/3)), 0)\n    qc.cry(math.pi/2, 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8032A2683C5C", "submission_order": 2, "result": "WA", "execution_time": "1730 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(1/3)), 0)\n    qc.cry(math.pi/2, 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8032A2683C5C", "submission_order": 3, "result": "AC", "execution_time": "1723 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(1/3)), 0)\n    qc.cry(math.pi/2, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A808B3CE26FCC", "submission_order": 1, "result": "UGE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    matrix = [ \n               [1, 0, 0, 0],\n               [0, 0, 1, 0],\n               [0, 1, 0, 0],\n               [0, 0, 0, 1] \n            ]\n    gate = UnitaryGate(matrix)\n    qc.append(gate, [0,1])        \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A808B3CE26FCC", "submission_order": 2, "result": "WA", "execution_time": "1384 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0,1)      \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A808B3CE26FCC", "submission_order": 3, "result": "WA", "execution_time": "1371 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0,1)      \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A808B3CE26FCC", "submission_order": 4, "result": "AC", "execution_time": "1500 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state = (np.sqrt(3) ** -1) * np.array([1,1,1,0])    \n    qc.initialize(state)\n    qc = qc.decompose().decompose().decompose().decompose().decompose().decompose()\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A811E3BF116A4", "submission_order": 1, "result": "WA", "execution_time": "1801 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A811E3BF116A4", "submission_order": 2, "result": "AC", "execution_time": "1796 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A81A2EDD2EE2E", "submission_order": 1, "result": "AC", "execution_time": "1620 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0) \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A82ADBB3BA54E", "submission_order": 1, "result": "WA", "execution_time": "1565 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.x(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A82ADBB3BA54E", "submission_order": 2, "result": "WA", "execution_time": "1574 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A82ADBB3BA54E", "submission_order": 3, "result": "WA", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A82ADBB3BA54E", "submission_order": 4, "result": "WA", "execution_time": "1741 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A82ADBB3BA54E", "submission_order": 5, "result": "WA", "execution_time": "1005 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.h(1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A82ADBB3BA54E", "submission_order": 6, "result": "UGE", "execution_time": "845 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.prepare_state([(3 ** 0.5) / 3, (3 ** 0.5) / 3, (3 ** 0.5) / 3, 0], qc.qubits)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A82ADBB3BA54E", "submission_order": 7, "result": "AC", "execution_time": "944 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8315E4173082", "submission_order": 1, "result": "WA", "execution_time": "833 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8315E4173082", "submission_order": 2, "result": "WA", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8315E4173082", "submission_order": 3, "result": "WA", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8315E4173082", "submission_order": 4, "result": "AC", "execution_time": "898 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A832A7251A2F1", "submission_order": 1, "result": "UGE", "execution_time": "1353 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    init = [1/math.sqrt(3), 1/math.sqrt(3), 1/math.sqrt(3), 0]\n    qc.initialize(init, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A832A7251A2F1", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info.operators import Operator\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    operator = Operator([\n        [1/math.sqrt(3), 0, 0, 0],\n        [1/math.sqrt(3), 0, 0, 0],\n        [1/math.sqrt(3), 0, 0, 0],\n        [1/math.sqrt(3), 0, 0, 0]\n    ])\n    qc.unitary(operator, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A832A7251A2F1", "submission_order": 3, "result": "AC", "execution_time": "1418 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n     \n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A845043B3213C", "submission_order": 1, "result": "WA", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A845043B3213C", "submission_order": 2, "result": "WA", "execution_time": "816 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A845043B3213C", "submission_order": 3, "result": "WA", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8476710ADE63", "submission_order": 1, "result": "WA", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8476710ADE63", "submission_order": 2, "result": "AC", "execution_time": "842 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A853DD02A76D8", "submission_order": 1, "result": "AC", "execution_time": "1898 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A85AFA60355FD", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.t(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(1)\n    qc.t(1)\n    qc.h(1)\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A85C0F1B885B3", "submission_order": 1, "result": "WA", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cz(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A88B7902B0927", "submission_order": 1, "result": "AC", "execution_time": "924 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8CAAAB248705", "submission_order": 1, "result": "AC", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    lis = []\n    k = 3\n    tmp = 0\n    while(k>0):\n        if k%2:\n            lis = lis + [tmp]\n        tmp += 1\n        k = k //2\n    m = 2 ** (lis[0])\n    \n    for i in range(1,len(lis)):\n        qc.x(lis[i])\n    if lis[0] > 0:\n        for i in range(lis[0]):\n            qc.h(i)\n    qc.ry(-2*math.acos(math.sqrt(m / 3)), lis[1])\n    qc.x(lis[1])\n    for i in range(lis[0],lis[1]):\n        qc.ch(lis[1], i)\n    qc.x(lis[1])        \n    for i in range(1,len(lis) - 1):\n        qc.x(lis[i]) \n        qc.cry(-2 * math.acos(math.sqrt(2 ** lis[i] / (3 - m))), lis[i], lis[i+1])\n        qc.x(lis[i])\n        qc.x(lis[i+1])\n        for j in range(lis[i],lis[i+1]):\n            qc.ch(lis[i+1],j)\n        qc.x(lis[i+1])\n        m = m + 2 ** (lis[i])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8DE8D49702B9", "submission_order": 1, "result": "RE", "execution_time": "754 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n    qc.u(math.pi*253/416,math.pi, math.pi,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8DE8D49702B9", "submission_order": 2, "result": "AC", "execution_time": "1303 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n    qc.u(math.pi*253/416,math.pi, math.pi,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8EFCCCB9C55C", "submission_order": 1, "result": "AC", "execution_time": "1703 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8F1B1FB14860", "submission_order": 1, "result": "WA", "execution_time": "1808 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    \n    qc.cz(0, 1)\n    \n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8F1B1FB14860", "submission_order": 2, "result": "WA", "execution_time": "1943 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h([0, 1])\n    \n    qc.cx(0, 1)\n\n    qc.h([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A8F1B1FB14860", "submission_order": 3, "result": "WA", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    \n    qc.cz(0, 1)\n    \n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A911CECC4FFD6", "submission_order": 1, "result": "RE", "execution_time": "945 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # 任意の複素振幅 a0, a1, a2 を使用\n    a0 = 0.6\n    a1 = 0.8\n    a2 = 0.3\n    \n    # アダマールゲートを各量子ビットに適用\n    qc.h(0)\n    qc.h(1)\n    \n    # U3ゲートを使用して任意の複素振幅を設定\n    qc.u3(2 * a0.real, 2 * a0.imag, 0, 0)  # U3ゲートを使用して振幅a0を適用\n    qc.u3(2 * a1.real, 2 * a1.imag, 0, 1)  # U3ゲートを使用して振幅a1を適用\n    qc.u3(2 * a2.real, 2 * a2.imag, 1, 0)  # U3ゲートを使用して振幅a2を適用\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9431E855C3B2", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A947800F9B647", "submission_order": 1, "result": "RE", "execution_time": "930 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,0)\n    qc.ch(0,1)\n    qc.cx(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A947800F9B647", "submission_order": 2, "result": "AC", "execution_time": "1005 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A94FF7ECF29BF", "submission_order": 1, "result": "WA", "execution_time": "789 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, CXGate, MCPhaseGate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qr = QuantumRegister(2)\n    qc = QuantumCircuit(qr)\n\n    # 最初の量子ビットにアダマールゲートを適用して重ね合わせを作成\n    h_gate = HGate()\n    qc.append(h_gate, [qr[0]])\n\n    # 適当な位相を追加して振幅を変更（例として）\n    angle_a1 = math.pi / 4  # a1 の位相\n    angle_a2 = math.pi / 3  # a2 の位相\n\n    # 量子ビット0が|1⟩の場合に量子ビット1に位相を追加\n    mcphase_gate_a1 = MCPhaseGate(angle_a1, 1)\n    qc.append(mcphase_gate_a1, [qr[0], qr[1]])\n\n    # CNOTゲートを適用してもつれを作成\n    cx_gate = CXGate()\n    qc.append(cx_gate, [qr[0], qr[1]])\n\n    # 量子ビット0が|0⟩の場合に量子ビット1に別の位相を追加\n    mcphase_gate_a2 = MCPhaseGate(angle_a2, 1)\n    qc.append(mcphase_gate_a2, [qr[0], qr[1]])\n\n    return qc\n\n# # 回路を表示\n# qc = solve()\n# print(qc)\n'''"}
{"problem": "QPC001_A4", "user": "A94FF7ECF29BF", "submission_order": 2, "result": "WA", "execution_time": "800 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, CXGate, RYGate, CU3Gate\n\ndef solve() -> QuantumCircuit:\n    # 量子レジスタを作成\n    qr = QuantumRegister(2)\n    qc = QuantumCircuit(qr)\n\n    # 回転角度を設定（これらは具体的な振幅に基づいて調整する必要があります）\n    theta_0 = 0  # RYの回転角度\n    theta_1, phi_1, lam_1 = 0, 0, 0  # 初めのCU3のパラメータ\n    theta_2, phi_2, lam_2 = 0, 0, 0  # 2つ目のCU3のパラメータ\n\n    # 回転ゲートを適用\n    qc.append(RYGate(theta_0), [qr[0]])\n    \n    # 制御U3ゲートを適用\n    qc.append(CU3Gate(theta_1, phi_1, lam_1), [qr[1], qr[0]])\n    \n    # CNOTゲートを適用\n    qc.append(CXGate(), [qr[1], qr[0]])\n\n    # さらに別の制御U3ゲートを適用\n    qc.append(CU3Gate(theta_2, phi_2, lam_2), [qr[1], qr[0]])\n\n    return qc\n\n\n# 回路を表示\n# qc = solve()\n# print(qc)\n'''"}
{"problem": "QPC001_A4", "user": "A94FF7ECF29BF", "submission_order": 3, "result": "WA", "execution_time": "822 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, CXGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # 1つ目の量子ビットにアダマールゲートを適用\n    qc.append(HGate(), [0])\n\n    # 任意の条件付き操作（例：制御NOTゲート）\n    qc.append(CXGate(), [0, 1])\n\n    # 他の必要な操作を追加\n\n    return qc\n\n# print(solve())\n'''"}
{"problem": "QPC001_A4", "user": "A94FF7ECF29BF", "submission_order": 4, "result": "WA", "execution_time": "814 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # アダマールゲートを適用して重ね合わせ状態を作成\n    qc.append(HGate(), [0])\n\n    # RY ゲートを使用して振幅を調整\n    angle = 2 * math.acos(1 / math.sqrt(3))\n    qc.append(RYGate(angle), [1])\n\n    # 制御NOTゲートを適用\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A94FF7ECF29BF", "submission_order": 5, "result": "AC", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # theta0 と theta1 を計算\n    theta0 = 2 * acos(1 / sqrt(3))\n    theta1 = 2 * acos(1 / sqrt(2))\n\n    # 最初の量子ビットに RY ゲートを適用\n    qc.ry(theta0, 0)\n\n    # 2番目の量子ビットに条件付き RY ゲートを適用\n    qc.cry(theta1, 0, 1)\n\n    # 最後に、2番目の量子ビットにアダマールゲートを適用\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A95DC176FE417", "submission_order": 1, "result": "RE", "execution_time": "1361 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(0, 2))\n    qc.cx(1, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A95DC176FE417", "submission_order": 2, "result": "WA", "execution_time": "1428 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(0, 2))\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A95DC176FE417", "submission_order": 3, "result": "WA", "execution_time": "1393 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0, 1])\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A95DC176FE417", "submission_order": 4, "result": "WA", "execution_time": "1388 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(0, 2))\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A95DC176FE417", "submission_order": 5, "result": "AC", "execution_time": "1511 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(0, 2))\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A966A6F72A6AB", "submission_order": 1, "result": "AC", "execution_time": "1512 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A96B4F26725CD", "submission_order": 1, "result": "WA", "execution_time": "1160 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A96B4F26725CD", "submission_order": 2, "result": "RE", "execution_time": "1158 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    if qc.measure(0) == qc.measure(1)==1:\n        qc.xc(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A96B4F26725CD", "submission_order": 3, "result": "AC", "execution_time": "1216 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A98CDBEE21938", "submission_order": 1, "result": "AC", "execution_time": "1466 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9924B99EC95A", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    state = np.array([1, 1, 1, 0])\n    qc.initialize(state)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9924B99EC95A", "submission_order": 2, "result": "RE", "execution_time": "771 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    state = [1, 1, 1, 0]\n    qc.initialize(state)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9924B99EC95A", "submission_order": 3, "result": "QLE", "execution_time": "762 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.h(0)\n    qc.h(1)\n    qc.ccx(0, 1, 2)\n    qc.reset(2)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9924B99EC95A", "submission_order": 4, "result": "AC", "execution_time": "856 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.t(1)\n    qc.cx(0, 1)\n    qc.tdg(1)\n    qc.cx(0, 1)\n    qc.t(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9A1837EAAEE1", "submission_order": 1, "result": "WA", "execution_time": "2000 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n\nprint(solve())\n'''"}
{"problem": "QPC001_A4", "user": "A9A1837EAAEE1", "submission_order": 2, "result": "QLE", "execution_time": "799 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9A1837EAAEE1", "submission_order": 3, "result": "WA", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2, 1)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9A1837EAAEE1", "submission_order": 4, "result": "UGE", "execution_time": "770 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.prepare_state([1/math.sqrt(3), 1/math.sqrt(3), 1/math.sqrt(3), 0], qc.qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9A1837EAAEE1", "submission_order": 5, "result": "UGE", "execution_time": "804 ms", "memory": "81 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.initialize([1/math.sqrt(3), 1/math.sqrt(3), 1/math.sqrt(3), 0], qc.qubits)\n\n    return qc\n\nprint(solve())\n'''"}
{"problem": "QPC001_A4", "user": "A9A1837EAAEE1", "submission_order": 6, "result": "AC", "execution_time": "1746 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n\nprint(solve())\n'''"}
{"problem": "QPC001_A4", "user": "A9A2D75FAC600", "submission_order": 1, "result": "RE", "execution_time": "755 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1)\n    qc.cx(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9A2D75FAC600", "submission_order": 2, "result": "WA", "execution_time": "1019 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9A2D75FAC600", "submission_order": 3, "result": "AC", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9BC32031172D", "submission_order": 1, "result": "WA", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9BC32031172D", "submission_order": 2, "result": "AC", "execution_time": "944 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9C7633C1C45F", "submission_order": 1, "result": "AC", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.asin(1.0/math.sqrt(3.0))\n    qc.ry(2.0 * theta,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 1, "result": "WA", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 2, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 3, "result": "WA", "execution_time": "918 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 4, "result": "WA", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 5, "result": "WA", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 6, "result": "WA", "execution_time": "901 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)    \n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 7, "result": "WA", "execution_time": "891 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) \n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 8, "result": "WA", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) \n    qc.h(1)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 9, "result": "WA", "execution_time": "805 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) \n    qc.h(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 10, "result": "WA", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) \n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 11, "result": "WA", "execution_time": "822 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) \n    qc.h(1)\n    qc.z(1)\n    qc.x(1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 12, "result": "WA", "execution_time": "1765 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) \n    qc.x(1)\n    qc.h(1)\n    qc.x(1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 13, "result": "WA", "execution_time": "875 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) \n    qc.x(0)\n    qc.h(1)\n    qc.x(1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 14, "result": "WA", "execution_time": "883 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.x(1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 15, "result": "WA", "execution_time": "833 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.h(1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 16, "result": "WA", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.h(1)\n    qc.x(1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9E4187A48528", "submission_order": 17, "result": "RE", "execution_time": "1702 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    a0 = 1/sqrt(3)\n    a1 = 1/sqrt(3)\n    a2 = 1/sqrt(3)\n    # The state is defined as:\n    #   |ψ⟩ = a0|00⟩ + a1|10⟩ + a2|01⟩.\n    #\n    # Qiskit's initialize expects a state vector in the order:\n    #   |00⟩, |01⟩, |10⟩, |11⟩.\n    # Thus we set:\n    #   amplitude for |00⟩ is a0,\n    #   amplitude for |01⟩ is a2,\n    #   amplitude for |10⟩ is a1,\n    #   amplitude for |11⟩ is 0.\n    state = [a0, a2, a1, 0]\n    \n    # Use the initialize instruction to prepare the state from |00>.\n    qc.initialize(state, [0, 1])    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9EFC1A40ED53", "submission_order": 1, "result": "AC", "execution_time": "1414 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 1, "result": "RE", "execution_time": "744 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state = [1/np.sqrt(3)]*3+[0]\n    qc.initialize(state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 2, "result": "RE", "execution_time": "742 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state = [1/np.sqrt(3)]*3\n    state.extend([0])\n    qc.initialize(state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_vector = [1/np.sqrt(3),1/np.sqrt(3), 1/np.sqrt(3),0]\n\n    state = Statevector(state_vector)\n    qc.initialize(state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 4, "result": "UGE", "execution_time": "761 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_vector = [1/math.sqrt(3),1/math.sqrt(3), 1/math.sqrt(3),0]\n\n    qc.initialize(state_vector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 5, "result": "RE", "execution_time": "1023 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_vector = [1/math.sqrt(3),1/math.sqrt(3), 1/math.sqrt(3)]\n\n    qc.initialize(state_vector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 6, "result": "RE", "execution_time": "1252 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_vector = [1/math.sqrt(3),1/math.sqrt(3), 1/math.sqrt(3)]\n\n    qc.initialize(state_vector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 7, "result": "UGE", "execution_time": "1867 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_vector = np.zeros(4)\n    for i in range(3):\n        state_vector[i]=1/np.sqrt(3)\n\n    qc.initialize(state_vector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 8, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_vector = np.zeros(4)\n    for i in range(4):\n        if i==1:\n            continue\n        state_vector[i]=1/np.sqrt(3)\n\n    qc.initialize(state_vector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 9, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_vector = np.zeros(4)\n    for i in range(4):\n        if i==1:\n            continue\n        state_vector[i]=1/np.sqrt(3)\n\n    qc.initialize(state_vector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 10, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_vector = np.zeros(4)\n    for i in range(3):\n        state_vector[i]=1/np.sqrt(3)\n    state=Statevector(state_vector)\n    qc.initialize(state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 11, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(3):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "A9FBB0C3C0572", "submission_order": 12, "result": "RE", "execution_time": "756 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(3):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA2014C35401E", "submission_order": 1, "result": "UGE", "execution_time": "1059 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state_list = [1/np.sqrt(3), 1/np.sqrt(3), 1/np.sqrt(3), 0]\n    qc.initialize(state_list, [0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA2014C35401E", "submission_order": 2, "result": "RE", "execution_time": "1053 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.u(pi/4, 0, 0, 0)\n    qc.u(1.23, 0, 0, 1)\n\n    qc.cx(0, 1)\n\n    qc.u(pi/4, 0, 0, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA2014C35401E", "submission_order": 3, "result": "RE", "execution_time": "1059 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.u(pi/4, 0, 0, 0)\n    qc.u(1.23, 0, 0, 1)\n\n    qc.cx(1, 0)\n\n    qc.u(pi/4, 0, 0, 0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA2014C35401E", "submission_order": 4, "result": "AC", "execution_time": "1102 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.u(np.pi/4, 0, 0, 0)\n    qc.u(1.23, 0, 0, 1)\n\n    qc.cx(1, 0)\n\n    qc.u(np.pi/4, 0, 0, 0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA35793A1445D", "submission_order": 1, "result": "UGE", "execution_time": "1895 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    # 複素振幅（任意の非ゼロ値）\n    a0 = 1 + 0j\n    a1 = 1j\n    a2 = -1\n    a3 = 0  # |11⟩には振幅なし（必須）\n\n    # 正規化（∑|a_i|^2 = 1 になるように）\n    norm = np.sqrt(abs(a0)**2 + abs(a1)**2 + abs(a2)**2)\n    state = [a0 / norm, a2 / norm, a1 / norm, a3]  # Qiskitの順番は: |00⟩, |01⟩, |10⟩, |11⟩\n\n    qc = QuantumCircuit(2)\n    qc.initialize(state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA35793A1445D", "submission_order": 2, "result": "RE", "execution_time": "1954 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # 任意の複素振幅（a0, a1, a2）を作るための例：ここでは簡易に実数比を使う\n    a0 = 1.0\n    a1 = 1.0\n    a2 = 1.0\n\n    # 正規化\n    norm = np.sqrt(a0**2 + a1**2 + a2**2)\n    a0 /= norm\n    a1 /= norm\n    a2 /= norm\n\n    # θ1: q0 の回転 → a0, a1 成分を作る\n    theta1 = 2 * np.arccos(a0 / np.sqrt(a0**2 + a1**2))\n    qc.u3(theta1, 0, 0, 0)\n\n    # CNOTで q0=0 のとき q1 に状態を分配するために条件反転\n    qc.x(0)\n\n    # θ2: q1 の回転 → a2 成分を q0=0 の条件下で注入\n    theta2 = 2 * np.arcsin(a2)\n    qc.cx(0, 1)\n    qc.u3(theta2, 0, 0, 1)\n    qc.cx(0, 1)\n\n    # q0 戻す\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA35793A1445D", "submission_order": 3, "result": "AC", "execution_time": "2018 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA4D47DB8ED01", "submission_order": 1, "result": "AC", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA526BEAC1EBD", "submission_order": 1, "result": "WA", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA55DA06D871E", "submission_order": 1, "result": "AC", "execution_time": "1385 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA61606E15899", "submission_order": 1, "result": "WA", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA61606E15899", "submission_order": 2, "result": "WA", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA712806968B2", "submission_order": 1, "result": "WA", "execution_time": "991 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA712806968B2", "submission_order": 2, "result": "WA", "execution_time": "850 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA712806968B2", "submission_order": 3, "result": "RE", "execution_time": "1318 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc2 = QuantumCircuit(1)\n\n    qc.h(0)\n    qc.x(1)\n    qc2.toffoli(qc[0], qc[1], qc2[0])\n    qc.cx(qc2[0], qc[1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA712806968B2", "submission_order": 4, "result": "AC", "execution_time": "1599 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA7B73C6EA772", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\n\ndef setting():\n    from qiskit_ibm_runtime import QiskitRuntimeService\n    import os\n    from dotenv import load_dotenv\n    load_dotenv()\n    TOKEN = os.getenv('qiskit_token')\n    QiskitRuntimeService.save_account(channel=\"ibm_quantum\", token=TOKEN, overwrite=True)\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\ndef draw_circuit(qc):\n    qc.measure_all()\n    qc.draw('mpl')\ndef simulate(qc):\n    from qiskit.providers.basic_provider import BasicSimulator\n    from qiskit.visualization import plot_histogram\n    backend = BasicSimulator()\n    result = backend.run(qc, shots=2000).result()\n    counts = result.get_counts()\n    plot_histogram(counts)\n\ndef debug(qc):\n    draw_circuit(qc)\n    simulate(qc)\ndef main():\n    debug(solve())\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC001_A4", "user": "AA7B73C6EA772", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\n\n\n# def setting():\n#     from qiskit_ibm_runtime import QiskitRuntimeService\n#     import os\n#     from dotenv import load_dotenv\n#     load_dotenv()\n#     TOKEN = os.getenv('qiskit_token')\n#     QiskitRuntimeService.save_account(channel=\"ibm_quantum\", token=TOKEN, overwrite=True)\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n\n# def draw_circuit(qc):\n#     qc.measure_all()\n#     qc.draw('mpl')\n# def simulate(qc):\n#     from qiskit.providers.basic_provider import BasicSimulator\n#     from qiskit.visualization import plot_histogram\n#     backend = BasicSimulator()\n#     result = backend.run(qc, shots=2000).result()\n#     counts = result.get_counts()\n#     plot_histogram(counts)\n\n# def debug(qc):\n#     draw_circuit(qc)\n#     simulate(qc)\n# def main():\n#     debug(solve())\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n    print(qc.draw(\"text\"))\n'''"}
{"problem": "QPC001_A4", "user": "AA7B73C6EA772", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\n\n\n# def setting():\n#     from qiskit_ibm_runtime import QiskitRuntimeService\n#     import os\n#     from dotenv import load_dotenv\n#     load_dotenv()\n#     TOKEN = os.getenv('qiskit_token')\n#     QiskitRuntimeService.save_account(channel=\"ibm_quantum\", token=TOKEN, overwrite=True)\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n\n# def draw_circuit(qc):\n#     qc.measure_all()\n#     qc.draw('mpl')\n# def simulate(qc):\n#     from qiskit.providers.basic_provider import BasicSimulator\n#     from qiskit.visualization import plot_histogram\n#     backend = BasicSimulator()\n#     result = backend.run(qc, shots=2000).result()\n#     counts = result.get_counts()\n#     plot_histogram(counts)\n\n# def debug(qc):\n#     draw_circuit(qc)\n#     simulate(qc)\n# def main():\n#     debug(solve())\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     from qiskit.quantum_info import Statevector\n#     print(Statevector(qc))\n#     print(qc.draw(\"text\"))\n'''"}
{"problem": "QPC001_A4", "user": "AA7B73C6EA772", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\nif __name__ == \"__main__\":\n    qc = solve()\n    from qiskit.quantum_info import Statevector\n    print(Statevector(qc))\n    print(qc.draw(\"text\"))\n'''"}
{"problem": "QPC001_A4", "user": "AA7B73C6EA772", "submission_order": 5, "result": "WA", "execution_time": "1612 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     # from qiskit.quantum_info import Statevector\n#     print(Statevector(qc))\n#     print(qc.draw(\"text\"))\n'''"}
{"problem": "QPC001_A4", "user": "AA7B73C6EA772", "submission_order": 6, "result": "WA", "execution_time": "1615 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA7B73C6EA772", "submission_order": 7, "result": "AC", "execution_time": "1600 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA82639E58C4F", "submission_order": 1, "result": "RE", "execution_time": "718 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.ch(1, 1)\n    return qc\n\n## 00\n## 0(0+1)\n## 00 01\n## 00+10+11\n## 00+10+01\n'''"}
{"problem": "QPC001_A4", "user": "AA82639E58C4F", "submission_order": 2, "result": "RE", "execution_time": "723 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 1)\n    return qc\n\n## 00\n## 0(0+1)\n## 00 01\n## 00+10+11\n## 00+10+01\n'''"}
{"problem": "QPC001_A4", "user": "AA82639E58C4F", "submission_order": 3, "result": "AC", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n\n## 00\n## (0+1)0\n## 00+10\n## 00+1(0+1)\n## 00+10+11\n## 00+10+01\n'''"}
{"problem": "QPC001_A4", "user": "AA828B34E3C81", "submission_order": 1, "result": "AC", "execution_time": "1070 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA868D8E51CA3", "submission_order": 1, "result": "WA", "execution_time": "954 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA868D8E51CA3", "submission_order": 2, "result": "WA", "execution_time": "1590 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA868D8E51CA3", "submission_order": 3, "result": "WA", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA868D8E51CA3", "submission_order": 4, "result": "AC", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA873CEEC1160", "submission_order": 1, "result": "WA", "execution_time": "1051 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA8CC0E36BFF9", "submission_order": 1, "result": "AC", "execution_time": "1490 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA949CB32D986", "submission_order": 1, "result": "AC", "execution_time": "1376 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA9CDFA02CDAA", "submission_order": 1, "result": "WA", "execution_time": "882 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA9CDFA02CDAA", "submission_order": 2, "result": "RE", "execution_time": "846 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA9CDFA02CDAA", "submission_order": 3, "result": "RE", "execution_time": "929 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA9CDFA02CDAA", "submission_order": 4, "result": "WA", "execution_time": "896 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA9CDFA02CDAA", "submission_order": 5, "result": "WA", "execution_time": "954 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA9CDFA02CDAA", "submission_order": 6, "result": "WA", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AA9CDFA02CDAA", "submission_order": 7, "result": "AC", "execution_time": "899 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAA59A3336EF3", "submission_order": 1, "result": "AC", "execution_time": "846 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ry(math.pi/4, 0)\n    qc.ry(math.pi/4, 1)\n    qc.cx(0, 1)\n    qc.ry(-math.pi/4, 0)\n    qc.ry(math.pi/2, 1)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAABBD1E34684", "submission_order": 1, "result": "WA", "execution_time": "1469 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAB960877A923", "submission_order": 1, "result": "AC", "execution_time": "1846 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cry(pi/2,0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AABBC4EB308E0", "submission_order": 1, "result": "WA", "execution_time": "1463 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AABBC4EB308E0", "submission_order": 2, "result": "RE", "execution_time": "1331 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = np.complex(1/np.sqrt(2), 1)\n    a1 = np.complex(1/np.sqrt(2), 1)\n    a2 = 1\n    qc.initialize([a0, a1, a2, 0], [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AABBC4EB308E0", "submission_order": 3, "result": "RE", "execution_time": "1371 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = 1\n    a1 = 1\n    a2 = 1\n    qc.initialize([a0, a1, a2, 0], [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AABBC4EB308E0", "submission_order": 4, "result": "UGE", "execution_time": "1366 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = 1/np.sqrt(3)\n    qc.initialize([a0, a0, a0, 0], [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AABBC4EB308E0", "submission_order": 5, "result": "WA", "execution_time": "1348 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    qc.h(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AABBC4EB308E0", "submission_order": 6, "result": "WA", "execution_time": "1332 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    qc.h(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AABBC4EB308E0", "submission_order": 7, "result": "WA", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    #qc.x(1)\n    qc.h(0)\n    qc.cp(-2 * np.arccos(1/np.sqrt(3)), 0, 1)\n    #qc.z(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 1, "result": "RE", "execution_time": "736 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.h(2)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 2, "result": "WA", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 3, "result": "WA", "execution_time": "820 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 4, "result": "WA", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 5, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 6, "result": "WA", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 7, "result": "WA", "execution_time": "814 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.x(0)\n    qc.x(1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 8, "result": "WA", "execution_time": "784 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 9, "result": "WA", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.x([0,1])\n    qc.x([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 10, "result": "WA", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.x([0,1])\n    qc.y([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 11, "result": "WA", "execution_time": "927 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.cx(0,1)\n    qc.x([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 12, "result": "WA", "execution_time": "903 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.x(0)\n    qc.x([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 13, "result": "WA", "execution_time": "822 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.y([0,1])\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 14, "result": "WA", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 15, "result": "WA", "execution_time": "1752 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 16, "result": "WA", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 17, "result": "WA", "execution_time": "1210 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 18, "result": "WA", "execution_time": "920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.i([1,0])\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 19, "result": "WA", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.i([1,0])\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 20, "result": "WA", "execution_time": "868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 21, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 22, "result": "WA", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 23, "result": "WA", "execution_time": "1719 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 24, "result": "WA", "execution_time": "824 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 25, "result": "WA", "execution_time": "956 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.i([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 26, "result": "WA", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 27, "result": "WA", "execution_time": "819 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx([0,1],[1,0])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 28, "result": "WA", "execution_time": "900 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.x([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 29, "result": "WA", "execution_time": "1143 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 30, "result": "WA", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 31, "result": "WA", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 32, "result": "WA", "execution_time": "910 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACC88F3A43D1", "submission_order": 33, "result": "WA", "execution_time": "1720 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACDDE5928E92", "submission_order": 1, "result": "RE", "execution_time": "761 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    cq.cx(0,1,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACDDE5928E92", "submission_order": 2, "result": "RE", "execution_time": "760 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    cq.crx(0.2, 0, 1, control_state=1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACDDE5928E92", "submission_order": 3, "result": "RE", "execution_time": "755 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    cq.crx(0.2, 0, 1, ctrl_state=1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACDDE5928E92", "submission_order": 4, "result": "WA", "execution_time": "964 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.crx(0.2, 0, 1, ctrl_state=1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AACDDE5928E92", "submission_order": 5, "result": "AC", "execution_time": "866 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.crx(0.2, 0, 1, ctrl_state=0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 1, "result": "WA", "execution_time": "819 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 2, "result": "WA", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.z(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 3, "result": "WA", "execution_time": "1169 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 4, "result": "WA", "execution_time": "849 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.y(0)\n    qc.y(1)\n    qc.x(0)\n    qc.x(1)\n    qc.h(1)\n    qc.h(0)\n    qc.cx(1,0)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 5, "result": "RE", "execution_time": "719 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from qiskit.circuit.library import YGate\n    for i in range(2):\n        qc.h(i)\n        qc.append(YGate,i)\n        qc.x(i)\n    \n    qc.h(1)\n    qc.cx(1,0)\n    qc.h(1)\n    qc.x(0)\n    qc.x(1)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 6, "result": "WA", "execution_time": "931 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(2):\n        qc.h(i)\n        qc.y(i)\n        qc.x(i)\n    \n    qc.h(1)\n    qc.cx(1,0)\n    qc.h(1)\n    qc.x(0)\n    qc.x(1)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 7, "result": "WA", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.h(1)\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 8, "result": "WA", "execution_time": "855 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    qc.h(0)\n    qc.h(1)\n    qc.ch(1,0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE4E4AE62653", "submission_order": 9, "result": "AC", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    qc.h(0)\n    qc.h(1)\n    qc.ch(1,0)\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE62EE105F4C", "submission_order": 1, "result": "WA", "execution_time": "1262 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cz(0,1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE62EE105F4C", "submission_order": 2, "result": "RE", "execution_time": "1227 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAE62EE105F4C", "submission_order": 3, "result": "AC", "execution_time": "1263 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAEF086ABF832", "submission_order": 1, "result": "WA", "execution_time": "1972 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAEF086ABF832", "submission_order": 2, "result": "AC", "execution_time": "1901 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AAF26606239C5", "submission_order": 1, "result": "AC", "execution_time": "1747 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB08F27516B8A", "submission_order": 1, "result": "WA", "execution_time": "1127 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB08F27516B8A", "submission_order": 2, "result": "RE", "execution_time": "1039 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB08F27516B8A", "submission_order": 3, "result": "AC", "execution_time": "1156 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB0AAD889CD2E", "submission_order": 1, "result": "AC", "execution_time": "1525 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(0.1,0)\n    qc.crx(0.1, 0, 1)\n    qc.x(0) \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB0ABB7A6DACE", "submission_order": 1, "result": "AC", "execution_time": "1358 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.ch(0,1)\n    qc.x([0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB13A8259CB25", "submission_order": 1, "result": "WA", "execution_time": "935 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB13A8259CB25", "submission_order": 2, "result": "WA", "execution_time": "811 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB13A8259CB25", "submission_order": 3, "result": "WA", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB13A8259CB25", "submission_order": 4, "result": "WA", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB13A8259CB25", "submission_order": 5, "result": "AC", "execution_time": "1599 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB2240083B199", "submission_order": 1, "result": "WA", "execution_time": "1662 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.asin(math.sqrt(1/3))\n    qc.ry(theta, 0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB2240083B199", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.asin(math.sqrt(1/3)\n    theta1 = 2 * math.asin(math.sqrt(1/2)\n    qc.ry(theta, 0)\n    qc.ry(theta1, 1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB2240083B199", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.asin(math.sqrt(1/3)\n    qc.ry(theta, 0)\n    qc.ry(math.pi/2, 1)\n    qc.cy(0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB2240083B199", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.asin(math.sqrt(1/3)\n    qc.ry(theta, 0)\n    qc.ry(math.pi/2, 1)\n    qc.cy(0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB2240083B199", "submission_order": 5, "result": "WA", "execution_time": "1750 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.asin(math.sqrt(1/3))\n    qc.ry(theta, 0)\n    qc.ry(math.pi/2, 1)\n    qc.cy(0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB2240083B199", "submission_order": 6, "result": "AC", "execution_time": "1655 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.asin(math.sqrt(1/3))\n    qc.ry(theta, 0)\n    qc.ry(math.pi/2, 1)\n    qc.cry(math.pi/2,0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB3297A19C0A6", "submission_order": 1, "result": "AC", "execution_time": "909 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.h(0)\n  qc.ch(0, 1)\n  qc.x(0)\n  return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB329F6E6AD6A", "submission_order": 1, "result": "RE", "execution_time": "807 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(2*math.acos(1/np.sqrt(3)),0,0,0)\n    qc.u(0,0,-math.pi/2,1)\n    qc.cx(0,1)\n    qc.u(math.pi/4,0,-math.pi/2,1)\n    qc.cx(0,1)\n    qc.u(math.pi,0,-math.pi/2,0)\n    qc.u(math.pi/4,0,math.pi,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB329F6E6AD6A", "submission_order": 2, "result": "WA", "execution_time": "885 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CHGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.append(CHGate(ctrl_state=0),[0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB329F6E6AD6A", "submission_order": 3, "result": "AC", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CHGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.append(CHGate(ctrl_state=0),[0,1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB4415A7C94D9", "submission_order": 1, "result": "AC", "execution_time": "999 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB44ED6344AD1", "submission_order": 1, "result": "WA", "execution_time": "845 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB44ED6344AD1", "submission_order": 2, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB482FBCB0D19", "submission_order": 1, "result": "WA", "execution_time": "831 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(1)\n    qc.cnot(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB482FBCB0D19", "submission_order": 2, "result": "WA", "execution_time": "828 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(1)\n    qc.cnot(0,1)\n    qc.z(0)\n    qc.z(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB482FBCB0D19", "submission_order": 3, "result": "WA", "execution_time": "1063 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cnot(0,1)\n    qc.h(0)\n    qc.h(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB482FBCB0D19", "submission_order": 4, "result": "WA", "execution_time": "1034 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cnot(0,1)\n    qc.h(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB482FBCB0D19", "submission_order": 5, "result": "WA", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cz(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB482FBCB0D19", "submission_order": 6, "result": "WA", "execution_time": "898 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cz(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB482FBCB0D19", "submission_order": 7, "result": "WA", "execution_time": "1473 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.y(1)\n    qc.h(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB482FBCB0D19", "submission_order": 8, "result": "AC", "execution_time": "1008 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(1.2310,0)\n    qc.ry(math.pi/4,1)\n    qc.x(0)\n    qc.cnot(0,1)\n    qc.x(0)\n    qc.ry(-1*math.pi/4,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB4DDE688092F", "submission_order": 1, "result": "AC", "execution_time": "948 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB5BA0AC6D6E0", "submission_order": 1, "result": "AC", "execution_time": "1600 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB6165763BE51", "submission_order": 1, "result": "WA", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB6165763BE51", "submission_order": 2, "result": "AC", "execution_time": "867 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB6E47DC10F04", "submission_order": 1, "result": "WA", "execution_time": "1137 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AB6E47DC10F04", "submission_order": 2, "result": "AC", "execution_time": "1120 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABB8A37FA02CD", "submission_order": 1, "result": "WA", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABBBEA5F8C79F", "submission_order": 1, "result": "UGE", "execution_time": "1479 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = 1  \n    a1 = 1  \n    a2 = 1  \n    a3 = 0  \n    \n    norm = (a0**2 + a1**2 + a2**2 + a3**2)**0.5\n    state = [a0/norm, a1/norm, a2/norm, a3/norm]\n    \n    # Initialize the qubits to the desired state\n    qc.initialize(state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABBBEA5F8C79F", "submission_order": 2, "result": "RE", "execution_time": "1481 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta1 = 2 * np.arccos(a0 / np.sqrt(a0**2 + a1**2))\n    qc.ry(theta1, 0)  # RY rotation on the first qubit\n    \n    # Step 2: Apply a controlled RY gate to the second qubit based on the first\n    theta2 = 2 * np.arccos(np.sqrt(a0**2 + a1**2) / np.sqrt(a0**2 + a1**2 + a2**2))\n    qc.cry(theta2, 0, 1)  # Controlled RY gate\n    \n    # Step 3: Apply a Pauli-X gate to flip the first qubit\n    qc.cx(0, 1)\n    \n    # Initialize the qubits to the desired state\n    qc.initialize(state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABBBEA5F8C79F", "submission_order": 3, "result": "RE", "execution_time": "1494 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta1 = 2 * math.acos(a0 / math.sqrt(a0**2 + a1**2))\n    qc.ry(theta1, 0)  # RY rotation on the first qubit\n    \n    # Step 2: Apply a controlled RY gate to the second qubit based on the first\n    theta2 = 2 * math.acos(math.sqrt(a0**2 + a1**2) / math.sqrt(a0**2 + a1**2 + a2**2))\n    qc.cry(theta2, 0, 1)  # Controlled RY gate\n    \n    # Step 3: Apply a CNOT gate to entangle the qubits\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABBBEA5F8C79F", "submission_order": 4, "result": "WA", "execution_time": "1421 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABBBEA5F8C79F", "submission_order": 5, "result": "RE", "execution_time": "1455 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta1 = 2 * math.acos(a0 / math.sqrt(a0**2 + a1**2))\n    qc.ry(theta1, 0)\n    \n    # Step 2: Apply Controlled RY gate on qubit 1 based on qubit 0 to adjust amplitude for |01>\n    theta2 = 2 * math.acos(a2 / math.sqrt(a1**2 + a2**2))\n    qc.ry(theta2, 1)\n    \n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABBBEA5F8C79F", "submission_order": 6, "result": "AC", "execution_time": "1393 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABC590A2D2393", "submission_order": 1, "result": "AC", "execution_time": "1422 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit.quantum_info import Statevector\nimport numpy as np\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    # qc.rxx(np.pi/10,0,1)\n    return qc\n\nqc = solve()\nprint(qc)\n#print(Statevector(qc))\n'''"}
{"problem": "QPC001_A4", "user": "ABC875C7D3A19", "submission_order": 1, "result": "RE", "execution_time": "756 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    from qiskit.circuit.library import HGate, CXGate, MCPhaseGate, MCMT\n    qc.h(0)\n    \n    ch = MCMT(HGate, 1, 1)\n    qc.append(ch)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABC875C7D3A19", "submission_order": 2, "result": "RE", "execution_time": "729 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    from qiskit.circuit.library import HGate, CXGate, MCPhaseGate, MCMT\n    qc.h(0)\n    \n    ch = MCMT(HGate, 1, 1)\n    qc.append(ch, qargs = [0, 1])\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABC875C7D3A19", "submission_order": 3, "result": "AC", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    from qiskit.circuit.library import HGate, CXGate, MCPhaseGate, MCMT\n    qc.h(0)\n    \n    qc.ch(0, 1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABCAEEFCFB78B", "submission_order": 1, "result": "AC", "execution_time": "1925 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABCB776EBABCA", "submission_order": 1, "result": "AC", "execution_time": "1967 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE14EF797755", "submission_order": 1, "result": "AC", "execution_time": "867 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import asin, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = asin(1 / sqrt(3))\n    qc.ry(theta * 2, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE161911D268", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import*\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cry(arccos(2*1/sqrt(3),0,1))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE161911D268", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import*\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cry(2*arccos(1/sqrt(3),0,1))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE161911D268", "submission_order": 3, "result": "RE", "execution_time": "758 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cry(2*arccos(1/sqrt(3),0,1))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE161911D268", "submission_order": 4, "result": "RE", "execution_time": "1491 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cry(2*np.arccos(1/np.sqrt(3),0,1))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE161911D268", "submission_order": 5, "result": "RE", "execution_time": "742 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cry(np.arccos(1/np.sqrt(3),1,0))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE161911D268", "submission_order": 6, "result": "RE", "execution_time": "804 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cry(math.acos(1/math.sqrt(3),1,0))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE161911D268", "submission_order": 7, "result": "RE", "execution_time": "935 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cry(math.acos(1/math.sqrt(3),1,0))\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ABE161911D268", "submission_order": 8, "result": "AC", "execution_time": "882 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cry(math.acos(1/math.sqrt(3)),1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC010F4C8172F", "submission_order": 1, "result": "WA", "execution_time": "1255 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x([0, 1])\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.x([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC010F4C8172F", "submission_order": 2, "result": "WA", "execution_time": "1272 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h([0, 1])\n    qc.x([0, 1])\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.x([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC010F4C8172F", "submission_order": 3, "result": "AC", "execution_time": "1269 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    \n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 1, "result": "WA", "execution_time": "800 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 2, "result": "WA", "execution_time": "1626 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 3, "result": "WA", "execution_time": "911 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 4, "result": "WA", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 5, "result": "RE", "execution_time": "1362 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(00)\n    qc.x(01)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 6, "result": "WA", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 7, "result": "WA", "execution_time": "1054 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h([0,1])\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 8, "result": "WA", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h([0,1])\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 9, "result": "WA", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 10, "result": "WA", "execution_time": "1744 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 11, "result": "WA", "execution_time": "966 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC0B423C580EF", "submission_order": 12, "result": "WA", "execution_time": "833 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC287C8A80CFD", "submission_order": 1, "result": "AC", "execution_time": "1587 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2A75FEC6DF3", "submission_order": 1, "result": "WA", "execution_time": "1092 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2A75FEC6DF3", "submission_order": 2, "result": "AC", "execution_time": "867 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n\n    theta_b = 1\n    theta_c = 0\n\n    qc.cry(theta_b, 0, 1)\n\n    qc.x(0)\n    qc.cry(theta_c, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 1, "result": "RE", "execution_time": "796 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 2, "result": "WA", "execution_time": "795 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 3, "result": "WA", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 4, "result": "WA", "execution_time": "1775 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 5, "result": "WA", "execution_time": "797 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cy(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 6, "result": "WA", "execution_time": "1731 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 7, "result": "WA", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 8, "result": "WA", "execution_time": "1694 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 9, "result": "WA", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC2FEF3D476CE", "submission_order": 10, "result": "RE", "execution_time": "853 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3ED84B1554D", "submission_order": 1, "result": "AC", "execution_time": "1497 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3F72C3D2D43", "submission_order": 1, "result": "WA", "execution_time": "1006 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cnot(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3F72C3D2D43", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    cntl_h = HGate().control(1)\n    qc.append(cntl_h, [1,0])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3F72C3D2D43", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import *\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    cntl_h = HGate().control(1)\n    qc.append(cntl_h, [1,0])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3F72C3D2D43", "submission_order": 4, "result": "WA", "execution_time": "958 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    cntl_h = HGate().control(1)\n    qc.append(cntl_h, [1,0])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3F72C3D2D43", "submission_order": 5, "result": "AC", "execution_time": "1087 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    cntl_h = HGate().control(1)\n    qc.append(cntl_h, [1,0])\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3FB1A34E781", "submission_order": 1, "result": "RE", "execution_time": "1503 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.CHGate(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3FB1A34E781", "submission_order": 2, "result": "WA", "execution_time": "1535 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3FB1A34E781", "submission_order": 3, "result": "RE", "execution_time": "1456 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.c(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3FB1A34E781", "submission_order": 4, "result": "RE", "execution_time": "1479 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC3FB1A34E781", "submission_order": 5, "result": "AC", "execution_time": "1631 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC5421E0E90E8", "submission_order": 1, "result": "WA", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cnot(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC5421E0E90E8", "submission_order": 2, "result": "WA", "execution_time": "882 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cnot(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC5421E0E90E8", "submission_order": 3, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC5421E0E90E8", "submission_order": 4, "result": "WA", "execution_time": "788 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC5421E0E90E8", "submission_order": 5, "result": "WA", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC5421E0E90E8", "submission_order": 6, "result": "AC", "execution_time": "810 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    # crx 90\n    qc.cry(0.1, 0, 1)\n    qc.x(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC65650F775D9", "submission_order": 1, "result": "RE", "execution_time": "741 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    a = 1 / math.sqrt(3)\n    qc.initialize([a, a, a, 0], [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC65650F775D9", "submission_order": 2, "result": "UGE", "execution_time": "752 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    a = 1 / math.sqrt(3)\n    qc.initialize([a, a, a, 0], [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC65650F775D9", "submission_order": 3, "result": "AC", "execution_time": "1063 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.ch(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC74FCD81CB52", "submission_order": 1, "result": "RE", "execution_time": "1326 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(n))\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC74FCD81CB52", "submission_order": 2, "result": "AC", "execution_time": "1327 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x((0,1))\n    qc.ch(0,1)\n    qc.x((0,1))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC75447CAD37A", "submission_order": 1, "result": "WA", "execution_time": "874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC75447CAD37A", "submission_order": 2, "result": "WA", "execution_time": "829 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC75447CAD37A", "submission_order": 3, "result": "AC", "execution_time": "901 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC7D8FB7DEEB5", "submission_order": 1, "result": "WA", "execution_time": "1448 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC7D8FB7DEEB5", "submission_order": 2, "result": "AC", "execution_time": "1442 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC83FAEB199EB", "submission_order": 1, "result": "WA", "execution_time": "1915 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC83FAEB199EB", "submission_order": 2, "result": "AC", "execution_time": "1877 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 1, "result": "WA", "execution_time": "1434 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 2, "result": "WA", "execution_time": "842 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n# Sゲートを適用して位相を変更\n    qc.s(0)\n\n# Tゲートを適用して位相を変更\n    qc.t(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 3, "result": "WA", "execution_time": "939 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 4, "result": "WA", "execution_time": "1007 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 5, "result": "RE", "execution_time": "830 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n\n    # 結果の状態をシミュレーターで取得\n    simulator = Aer.get_backend('statevector_simulator')\n    compiled_circuit = transpile(qc, simulator)\n    result = simulator.run(compiled_circuit).result()\n\n    # 量子ビットの状態ベクトルを取得\n    statevector = result.get_statevector()\n\n    # 1/sqrt(3) を掛ける\n    statevector /= (statevector[0] + statevector[2] + statevector[3]) / 3.0\n\n    # 量子回路を再構築\n    qc = QuantumCircuit(2)\n    qc.initialize(statevector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 6, "result": "WA", "execution_time": "1277 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 7, "result": "WA", "execution_time": "1098 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 8, "result": "WA", "execution_time": "980 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n\n# CNOTゲートを適用\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 9, "result": "RE", "execution_time": "739 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Hadamardゲートを適用して重ね合わせ状態を生成\n    qc.h(0)\n\n    # 2番目のキュビットにXゲートを適用して|1⟩状態を作成\n    qc.x(1)\n\n    # 制御位相回転ゲートを適用して目標の状態を生成\n    qc.cu3(2 * a1.real, 0, 0, 1, 0)  # cu3(theta, phi, lambda, control_qubit, target_qubit)\n    qc.cu3(2 * a2.real, 0, 0, 0, 1)\n\n    qc.u1(2 * a0.imag, 0)  # u1(lambda, target_qubit)\n    qc.u1(2 * a1.imag, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 10, "result": "RE", "execution_time": "776 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Hadamardゲートを適用して重ね合わせ状態を生成\n    qc.h(0)\n\n    # 2番目のキュビットにXゲートを適用して|1⟩状態を作成\n    qc.x(1)\n\n    # 制御位相回転ゲートを適用して目標の状態を生成\n    qc.cu3(2 * 0.1, 0, 0, 1, 0)  # cu3(theta, phi, lambda, control_qubit, target_qubit)\n    qc.cu3(2 * 0.2, 0, 0, 0, 1)\n\n    qc.u1(2 * 0.1, 0)  # u1(lambda, target_qubit)\n    qc.u1(2 * 0.1, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 11, "result": "WA", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 12, "result": "WA", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 13, "result": "WA", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 14, "result": "WA", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 15, "result": "WA", "execution_time": "862 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 16, "result": "WA", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 17, "result": "WA", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 18, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 19, "result": "WA", "execution_time": "1254 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(1)\n    qc.h(1)\n    qc.cx(0, 1)  # CXゲートを追加して|11⟩を回避\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 20, "result": "WA", "execution_time": "911 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.x(1)\n    qc.h(1)\n    qc.cx(0, 1)  # CXゲートを追加して|11⟩を回避\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 21, "result": "WA", "execution_time": "1510 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)  # CXゲートを追加して|11⟩を回避\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 22, "result": "WA", "execution_time": "912 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.h(1)\n\n    # CNOTゲートを適用してエンタングル状態を作成\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 23, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.h(1)\n\n    # CNOTゲートを適用してエンタングル状態を作成\n    qc.cx(0, 1)\n    #qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 24, "result": "WA", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.h(1)\n\n    # CNOTゲートを適用してエンタングル状態を作成\n    #qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 25, "result": "WA", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.h(1)\n\n    qc.cz(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 26, "result": "WA", "execution_time": "1086 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(1, 0)\n    qc.cz(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 27, "result": "WA", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    #qc.h(1)\n\n    qc.cx(1, 0)\n    qc.cz(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 28, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    #qc.h(1)\n\n    qc.cx(1, 0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 29, "result": "WA", "execution_time": "1960 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    #qc.h(1)\n\n    qc.cx(1, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 30, "result": "WA", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.h(1)\n\n    # 制御NOTゲートを適用してエンタングル状態を作成\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 31, "result": "WA", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.swap(0, 1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 32, "result": "WA", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.swap(0, 1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 33, "result": "WA", "execution_time": "1085 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.swap(0, 1)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 34, "result": "WA", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.swap(0, 1)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 35, "result": "WA", "execution_time": "936 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.swap(0, 1)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 36, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.cz(0, 1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AC8E3C5D7CD25", "submission_order": 37, "result": "WA", "execution_time": "981 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.h(1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC605073214E", "submission_order": 1, "result": "RE", "execution_time": "1909 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 1, "result": "WA", "execution_time": "913 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 2, "result": "WA", "execution_time": "910 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 3, "result": "RE", "execution_time": "876 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    U = np.array([[1, 0, 0, 0],\n                  [0, 0, 1, 0],\n                  [0, 1, 0, 0],\n                  [0, 0, 0, 1]])\n    qc.unitary(Operator(U), [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Operator\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    U = np.array([[1, 0, 0, 0],\n                  [0, 0, 1, 0],\n                  [0, 1, 0, 0],\n                  [0, 0, 0, 1]])\n    qc.unitary(Operator(U), [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 5, "result": "WA", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = 1 / math.sqrt(3)\n    a1 = 1 / math.sqrt(3)\n    a2 = 1 / math.sqrt(3)\n\n    qc.ry(2 * math.acos(a2), 0)\n\n    qc.cx(0, 1)\n    qc.ry(2 * math.asin(a1 / math.sqrt(a1**2 + a0**2)), 1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 6, "result": "RE", "execution_time": "772 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, XGate, RXGate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n     qc.append(HGate(), [0])\n\n    qc.append(XGate(), [1])\n    qc.append(RXGate(math.pi / 2), [1]) \n    qc.append(XGate(), [1])  \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 7, "result": "WA", "execution_time": "930 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, XGate, RXGate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.append(HGate(), [0])\n\n    qc.append(XGate(), [1])\n    qc.append(RXGate(math.pi / 2), [1])\n    qc.append(XGate(), [1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 8, "result": "WA", "execution_time": "932 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n\n    qc.cry(pi/2, 0, 1)\n\n    qc.x(0)\n    qc.cry(-pi/2, 0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 9, "result": "RE", "execution_time": "759 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cry(2 * math.acos(1 / math.sqrt(3)), 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 10, "result": "RE", "execution_time": "1167 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cp(math.pi/2, 0, 1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 11, "result": "RE", "execution_time": "1023 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 12, "result": "RE", "execution_time": "917 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 13, "result": "RE", "execution_time": "753 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cry(2 * np.arctan((a1 + a2) / (a0 + a2)), 0, 1)\n    qc.crz(2 * np.arctan(a2 / a1), 0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 14, "result": "RE", "execution_time": "743 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cry(2 * math.atan((a1 + a2) / (a0 + a2)), 0, 1)\n    qc.crz(2 * math.atan(a2 / a1), 0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 15, "result": "RE", "execution_time": "770 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cry(2 * math.atan(2/ 3), 0, 1)\n    qc.crz(2 * math.atan(1 / 3), 0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 16, "result": "RE", "execution_time": "790 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.rz(2 * math.atan(2/3), 0, 1)\n    qc.rz(2 * math.atan(1/3), 0, 1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACC65F6CF798A", "submission_order": 17, "result": "RE", "execution_time": "837 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.rz(2 * math.atan(2/3), 0)\n    qc.rz(2 * math.atan(1/3), 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACCEB9E6623EF", "submission_order": 1, "result": "RE", "execution_time": "730 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.append(ZGate().control(n - 1), range(n))\n    theta = math.acos(1 / 3 ** 0.5)\n    qc.rx(theta, 1)\n    qc.ch(1, 0)\n    qc.cp(-math.pi / 4, 1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACCEB9E6623EF", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1 / (3 ** 0.5))\n    qc.rx(theta, 1)\n    qc.ch(1, 0)\n    qc.cp(-math.pi / 4, 1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACCEB9E6623EF", "submission_order": 3, "result": "RE", "execution_time": "842 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit()\n    # Write your code here:\n    theta = math.acos(1 / (3 ** 0.5))\n    qc.rx(theta, 1)\n    qc.ch(1, 0)\n    qc.cp(-math.pi / 4, 1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACCEB9E6623EF", "submission_order": 4, "result": "AC", "execution_time": "1110 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1 / (3 ** 0.5))\n    qc.rx(theta, 1)\n    qc.ch(1, 0)\n    qc.cp(-math.pi / 4, 1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACD258C822E9D", "submission_order": 1, "result": "AC", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACD40DFFDBEFB", "submission_order": 1, "result": "UGE", "execution_time": "775 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.initialize([1/sqrt(3),1/sqrt(3),1/sqrt(3),0],[0,1])\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACD40DFFDBEFB", "submission_order": 2, "result": "AC", "execution_time": "843 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 1, "result": "WA", "execution_time": "953 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 2, "result": "WA", "execution_time": "997 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cnot(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 3, "result": "WA", "execution_time": "960 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 4, "result": "WA", "execution_time": "811 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cnot(0,1)\n    qc.u(1,0,0, qubit=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 5, "result": "RE", "execution_time": "822 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc = QuantumCircuit(2)\n    qc.u(1.91,0, math.pi,0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 6, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(1.91, 0, math.pi,0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 7, "result": "WA", "execution_time": "929 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(1.91, 0, math.pi,0)\n    qc.cnot(1,0 )\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 8, "result": "WA", "execution_time": "1665 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1, 0)\n    qc.csx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACDB0D9456FD5", "submission_order": 9, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(1.91, 0, math.pi, qubit=0)\n    qc.cx(1, 0)\n    qc.csx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ACE94E9D27288", "submission_order": 1, "result": "AC", "execution_time": "1713 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0, 1)\n    qc.h(1)\n    qc.cry(math.pi/2, 0, 1)\n\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD0104E679998", "submission_order": 1, "result": "AC", "execution_time": "2161 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * math.acos(math.sqrt(2/3))\n    qc.ry(theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD02E93F00D0A", "submission_order": 1, "result": "WA", "execution_time": "805 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cnot(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD02E93F00D0A", "submission_order": 2, "result": "AC", "execution_time": "743 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cnot(1,0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD0481FA8183E", "submission_order": 1, "result": "AC", "execution_time": "885 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 1, "result": "RE", "execution_time": "1362 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nfrom numpy import arccos, sqrt\n\ndef solve(a0: float, a1: float, a2: float) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Step 1: Normalize coefficients\n    norm = sqrt(a0**2 + a1**2 + a2**2)\n    a0 /= norm\n    a1 /= norm\n    a2 /= norm\n\n    # Step 2: Create superposition using Ry gate\n    theta1 = 2 * arccos(a0)\n    qc.ry(theta1, 0)\n\n    # Step 3: Use CNOT to entangle qubits\n    if a1 != 0:\n        qc.cx(0, 1)\n    \n    # Step 4: Adjust the amplitude using Ry gate on the second qubit\n    if a2 != 0:\n        theta2 = 2 * arccos(a2 / sqrt(a1**2 + a2**2))\n        qc.ry(theta2, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 2, "result": "RE", "execution_time": "1322 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(a0: float, a1: float, a2: float) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Step 1: Normalize coefficients\n    norm = sqrt(a0**2 + a1**2 + a2**2)\n    a0 /= norm\n    a1 /= norm\n    a2 /= norm\n\n    # Step 2: Create superposition using Ry gate\n    theta1 = 2 * arccos(a0)\n    qc.ry(theta1, 0)\n\n    # Step 3: Use CNOT to entangle qubits\n    if a1 != 0:\n        qc.cx(0, 1)\n    \n    # Step 4: Adjust the amplitude using Ry gate on the second qubit\n    if a2 != 0:\n        theta2 = 2 * arccos(a2 / sqrt(a1**2 + a2**2))\n        qc.ry(theta2, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 3, "result": "RE", "execution_time": "1300 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(a0: float, a1: float, a2: float) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Step 1: Normalize coefficients\n    norm = sqrt(a0**2 + a1**2 + a2**2)\n    a0 /= norm\n    a1 /= norm\n    a2 /= norm\n\n    # Step 2: Create superposition using Ry gate\n    theta1 = 2 * arccos(a0)\n    qc.ry(theta1, 0)\n\n    # Step 3: Use CNOT to entangle qubits\n    if a1 != 0:\n        qc.cx(0, 1)\n    \n    # Step 4: Adjust the amplitude using Ry gate on the second qubit\n    #if a2 != 0:\n    #    theta2 = 2 * arccos(a2 / sqrt(a1**2 + a2**2))\n    #    qc.ry(theta2, 1)\n\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 4, "result": "RE", "execution_time": "1340 ms", "memory": "139 MiB", "code": "'''python\nimport math\nimport numpy\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, CXGate\n\ndef solve(a0: float, a1: float, a2: float) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Step 1: Normalize coefficients\n    norm = math.sqrt(a0**2 + a1**2 + a2**2)\n    a0 /= norm\n    a1 /= norm\n    a2 /= norm\n\n    # Step 2: Apply RY gate to the first qubit to create superposition\n    theta1 = 2 * math.acos(a0)\n    qc.append(RYGate(theta1), [0])\n\n    # Step 3: Apply CNOT gate to entangle qubits\n    qc.append(CXGate(), [0, 1])\n    \n    # Step 4: Adjust the second qubit's state based on the desired superposition\n    if a1 != 0 or a2 != 0:\n        theta2 = 2 * math.acos(a2 / math.sqrt(a1**2 + a2**2))\n        qc.append(RYGate(theta2), [1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 5, "result": "WA", "execution_time": "1346 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Create a superposition state on the first qubit using a custom unitary operation\n    theta = 2 * np.arccos(1/np.sqrt(3))\n    qc.ry(theta, 0)\n    \n    # Step 2: Apply a CNOT gate to create entanglement between the first and second qubit\n    qc.cx(0, 1)\n    \n    # Step 3: Apply an X gate on the second qubit to get the superposition of 00, 10, and 01\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 6, "result": "WA", "execution_time": "1301 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n\n    # Step 2: Apply a CNOT gate to entangle the qubits\n    qc.cx(0, 1)\n\n    # Step 3: Apply an X gate to the first qubit to flip its state (inverting the first qubit)\n    qc.x(0)\n    \n    # Step 4: Apply another Hadamard gate to the first qubit to adjust the superposition\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 7, "result": "RE", "execution_time": "1336 ms", "memory": "140 MiB", "code": "'''python\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Step 1: Set the first qubit in a superposition state using H gate and phase rotation\n    qc.h(0)\n    qc.p(np.pi/2, 0)  # Apply phase to match the desired amplitudes\n\n    # Step 2: Use Ry gate to adjust the amplitude for the |10⟩ and |01⟩ components\n    qc.ry(2*np.arccos(1/np.sqrt(2)), 0)  # Adjust the first qubit's amplitude\n    \n    # Step 3: Entangle the qubits using a CNOT gate\n    qc.cx(0, 1)\n    \n    # Step 4: Apply Ry gate on the second qubit to adjust the amplitude for the |01⟩ state\n    qc.ry(np.pi/2, 1)  # Adjust the second qubit's amplitude\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 8, "result": "WA", "execution_time": "1204 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Step 1: Set the first qubit in a superposition state using H gate and phase rotation\n    qc.h(0)\n    qc.p(np.pi/2, 0)  # Apply phase to match the desired amplitudes\n\n    # Step 2: Use Ry gate to adjust the amplitude for the |10⟩ and |01⟩ components\n    qc.ry(2*np.arccos(1/np.sqrt(2)), 0)  # Adjust the first qubit's amplitude\n    \n    # Step 3: Entangle the qubits using a CNOT gate\n    qc.cx(0, 1)\n    \n    # Step 4: Apply Ry gate on the second qubit to adjust the amplitude for the |01⟩ state\n    qc.ry(np.pi/2, 1)  # Adjust the second qubit's amplitude\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD1B713FD6B71", "submission_order": 9, "result": "AC", "execution_time": "1189 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD298AEA0CE88", "submission_order": 1, "result": "AC", "execution_time": "1353 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD2C3B00950A2", "submission_order": 1, "result": "AC", "execution_time": "846 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)         \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD2CE9885CD62", "submission_order": 1, "result": "RE", "execution_time": "1600 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here: \n    q.h(range(2))\n    q.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD2CE9885CD62", "submission_order": 2, "result": "RE", "execution_time": "1570 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here: \n    q.h(range(2))\n    q.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD2CE9885CD62", "submission_order": 3, "result": "RE", "execution_time": "1598 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here: \n    q.h(0)\n    q.h(1)\n    q.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD2CE9885CD62", "submission_order": 4, "result": "RE", "execution_time": "1677 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here: \n    q.h(0)\n    q.ch(0,1)\n    q.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD2CE9885CD62", "submission_order": 5, "result": "RE", "execution_time": "1534 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here: \n    q.h(0)\n    q.ch(0,1)\n    q.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD2CE9885CD62", "submission_order": 6, "result": "AC", "execution_time": "1669 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here: \n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD2F391E5E7AE", "submission_order": 1, "result": "AC", "execution_time": "863 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 1, "result": "RE", "execution_time": "797 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(0, 0.1)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 2, "result": "WA", "execution_time": "901 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(0.1, 0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 3, "result": "WA", "execution_time": "1064 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(0.1, 0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 4, "result": "WA", "execution_time": "918 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 5, "result": "WA", "execution_time": "916 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 6, "result": "WA", "execution_time": "959 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 7, "result": "WA", "execution_time": "1014 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 8, "result": "WA", "execution_time": "977 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ch(0,1, ctrl_state=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 9, "result": "WA", "execution_time": "986 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ch(1,0, ctrl_state=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD5A134B862BC", "submission_order": 10, "result": "AC", "execution_time": "980 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0, ctrl_state=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD605B22770B4", "submission_order": 1, "result": "AC", "execution_time": "1404 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6111FF98DA2", "submission_order": 1, "result": "AC", "execution_time": "2590 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit import Parameter\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    a0 = Parameter('a0')\n    a1 = Parameter('a1')\n    a2 = Parameter('a2')\n    \n    # Prepare the state |ψ⟩ = a0|00⟩ + a1|10⟩ + a2|01⟩\n    qc.initialize([a0, 0, a2, 0, a1, 0, 0, 0], [0, 1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 2, "result": "RE", "execution_time": "1833 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Define arbitrary non-zero probability amplitudes\n    a0 = np.sqrt(0.5)  # Example value for a0\n    a1 = np.sqrt(0.3)  # Example value for a1\n    a2 = np.sqrt(0.2)  # Example value for a2\n    \n    # Apply the appropriate gates to prepare the state |ψ⟩\n    qc.initialize([a0, 0, a1, 0, a2, 0, 0, 0], [0, 1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 3, "result": "RE", "execution_time": "1909 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    a0 = np.sqrt(0.5)  # Example amplitude for |00>\n    a1 = np.sqrt(0.3)  # Example amplitude for |10>\n    a2 = np.sqrt(0.2)  # Example amplitude for |01>\n    \n    # Apply a rotation to create the superposition state\n    qc.ry(2 * np.arccos(a0), 0)  # Rotate qubit 0\n    qc.ry(2 * np.arccos(a1 / np.sqrt(1 - a0**2)), 1)  # Rotate qubit 1\n    \n    # Apply a controlled rotation to create the |01> component\n    qc.cu3(2 * np.arccos(a2 / np.sqrt(1 - a0**2 - a1**2)), 0, 0, 0, 1)  # Controlled rotation\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RY, RZ, CX\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Define arbitrary non-zero probability amplitudes\n    a0 = 1 / math.sqrt(2)  # Amplitude for |00>\n    a1 = 1 / math.sqrt(2)  # Amplitude for |10>\n    a2 = 0                 # Amplitude for |01> (set to 0 for this example)\n    \n    # Prepare the state |ψ> = a0|00> + a1|10> + a2|01>\n    # Apply RY and RZ rotations to create the superposition\n    qc.ry(2 * math.acos(a0), 0)  # Rotate qubit 0\n    qc.ry(2 * math.acos(a1), 1)  # Rotate qubit 1\n    \n    # Apply a controlled-X gate to create the |10> state\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 5, "result": "WA", "execution_time": "1793 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CXGate\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Define arbitrary amplitudes\n    a0 = np.sqrt(0.5)  # Amplitude for |00>\n    a1 = np.sqrt(0.3)  # Amplitude for |10>\n    a2 = np.sqrt(0.2)  # Amplitude for |01>\n    \n    # Apply a Hadamard gate to create superposition\n    qc.h(0)  # Create superposition on qubit 0\n    \n    # Apply a controlled-X (CNOT) gate to entangle qubits\n    qc.cx(0, 1)  # Control qubit 0, target qubit 1\n    \n    # Apply rotation gates to adjust amplitudes\n    qc.ry(2 * np.arccos(a0), 0)  # Adjust amplitude for |00>\n    qc.ry(2 * np.arccos(a1), 1)  # Adjust amplitude for |10>\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 6, "result": "WA", "execution_time": "1898 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Define arbitrary amplitudes\n    a0 = np.sqrt(0.5)  # Amplitude for |00>\n    a1 = np.sqrt(0.3)  # Amplitude for |10>\n    a2 = np.sqrt(0.2)  # Amplitude for |01>\n    \n    # Apply a Hadamard gate to create superposition\n    qc.h(0)  # Create superposition on qubit 0\n    \n    # Apply a controlled-X (CNOT) gate to entangle qubits\n    qc.cx(0, 1)  # Control qubit 0, target qubit 1\n    \n    # Apply rotation gates to adjust amplitudes\n    qc.ry(2 * np.arccos(a0), 0)  # Adjust amplitude for |00>\n    qc.ry(2 * np.arccos(a1), 1)  # Adjust amplitude for |10>\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 7, "result": "WA", "execution_time": "1932 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Define arbitrary amplitudes\n    a0 = np.sqrt(0.5)  # Amplitude for |00>\n    a1 = np.sqrt(0.3)  # Amplitude for |10>\n    a2 = np.sqrt(0.2)  # Amplitude for |01>\n    \n    # Apply a Hadamard gate to create superposition\n    qc.h(0)  # Create superposition on qubit 0\n    \n    # Apply a controlled-X (CNOT) gate to entangle qubits\n    qc.ch(0, 1)  # Control qubit 0, target qubit 1\n    \n    # Apply rotation gates to adjust amplitudes\n    qc.ry(2 * np.arccos(a0), 0)  # Adjust amplitude for |00>\n    qc.ry(2 * np.arccos(a1), 1)  # Adjust amplitude for |10>\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 8, "result": "WA", "execution_time": "1906 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Define arbitrary amplitudes\n    a0 = np.sqrt(0.5)  # Amplitude for |00>\n    a1 = np.sqrt(0.3)  # Amplitude for |10>\n    a2 = np.sqrt(0.2)  # Amplitude for |01>\n    \n    # Apply a Hadamard gate to create superposition\n    qc.h(0)  # Create superposition on qubit 0\n    \n    # Apply a controlled-X (CNOT) gate to entangle qubits\n    qc.ch(0, 1)  # Control qubit 0, target qubit 1\n    \n    # Apply rotation gates to adjust amplitudes\n    qc.ry(2 * np.arccos(a0), 0)  # Adjust amplitude for |00>\n    qc.ry(2 * np.arccos(a1), 1)  # Adjust amplitude for |10>\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 9, "result": "WA", "execution_time": "1848 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    a0 = np.sqrt(0.5)  # Example amplitude for |00>\n    a1 = np.sqrt(0.3)  # Example amplitude for |10>\n    a2 = np.sqrt(0.2)  # Example amplitude for |01>\n    \n    # Apply a rotation to create the superposition state\n    qc.ry(2 * np.arccos(a0), 0)  # Rotate qubit 0\n    qc.ry(2 * np.arccos(a1 / np.sqrt(1 - a0**2)), 1)  # Rotate qubit 1\n    \n    # Apply a controlled rotation to create the |01> component\n    qc.cx(0, 1)  # Control qubit 0 to qubit 1\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD6D7AADD8A54", "submission_order": 10, "result": "WA", "execution_time": "1917 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Define the amplitudes\n    a0 = 1 / np.sqrt(2)\n    a1 = 1 / np.sqrt(3)\n    a2 = 1 / np.sqrt(6)\n\n    # Apply RY rotations to create the superposition\n    # The angles are derived from the amplitudes\n    theta1 = 2 * np.arccos(a0)  # For |00>\n    theta2 = 2 * np.arccos(np.sqrt(a1 / (a1 + a2)))  # For |10> and |01>\n\n    # Create the state |00> + |10> + |01>\n    qc.ry(theta1, 0)  # Rotate qubit 0\n    qc.ry(theta2, 1)  # Rotate qubit 1\n\n    # Apply a controlled rotation to create the |10> and |01> states\n    qc.cx(0, 1)  # CNOT gate to create the |10> state\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD7381196059B", "submission_order": 1, "result": "AC", "execution_time": "1338 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD83723C54809", "submission_order": 1, "result": "RE", "execution_time": "762 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(2*pi, 1)\n    qc.rx(2*pi, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AD87F985DFDD5", "submission_order": 1, "result": "AC", "execution_time": "866 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADA3D22295206", "submission_order": 1, "result": "AC", "execution_time": "899 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADA8FE7CAD069", "submission_order": 1, "result": "WA", "execution_time": "1214 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADA8FE7CAD069", "submission_order": 2, "result": "WA", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADA8FE7CAD069", "submission_order": 3, "result": "AC", "execution_time": "806 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADB21B781F96E", "submission_order": 1, "result": "WA", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cz(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADB21B781F96E", "submission_order": 2, "result": "AC", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADC08A661C03E", "submission_order": 1, "result": "UGE", "execution_time": "1418 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = 1/np.sqrt(3)  # Example amplitude for |00>\n    a1 = 1/np.sqrt(3)  # Example amplitude for |10>\n    a2 = 1/np.sqrt(3)  # Example amplitude for |01>\n    \n    # Normalize the amplitudes to ensure they form a valid quantum state\n    norm = np.sqrt(abs(a0)**2 + abs(a1)**2 + abs(a2)**2)\n    a0, a1, a2 = a0 / norm, a1 / norm, a2 / norm\n    \n    # The target state vector: [a0, a2, a1, 0]\n    state_vector = [a0, a2, a1, 0]\n    \n    # Initialize the qubits to the desired state\n    qc.initialize(state_vector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADC08A661C03E", "submission_order": 2, "result": "RE", "execution_time": "1457 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a0 = 1/np.sqrt(3)  # Example amplitude for |00>\n    a1 = 1/np.sqrt(3)  # Example amplitude for |10>\n    a2 = 1/np.sqrt(3)  # Example amplitude for |01>\n    \n    # Normalize the amplitudes to ensure they form a valid quantum state\n    norm = np.sqrt(abs(a0)**2 + abs(a1)**2 + abs(a2)**2)\n    a0, a1, a2 = a0 / norm, a1 / norm, a2 / norm\n    \n    # The target state vector: [a0, a2, a1, 0]\n    state_vector = [a0, a2, a1, 0]\n    \n    # Initialize the qubits to the desired state\n    qc.initialize(state_vector, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADCD2EA601189", "submission_order": 1, "result": "AC", "execution_time": "1535 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, CXGate, CHGate\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\t# Write your code here:\n\tqc.append(HGate(), [0])\n\tqc.append(CHGate(), [0, 1])\n\tqc.append(CXGate(), [1, 0])\n\treturn qc\n'''"}
{"problem": "QPC001_A4", "user": "ADD2F67EC1706", "submission_order": 1, "result": "AC", "execution_time": "937 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADDB2106B2513", "submission_order": 1, "result": "AC", "execution_time": "1972 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADE6D13053DC9", "submission_order": 1, "result": "AC", "execution_time": "1524 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADEC81687F8C3", "submission_order": 1, "result": "RE", "execution_time": "1408 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0, cx(1,1))\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADEC81687F8C3", "submission_order": 2, "result": "RE", "execution_time": "1407 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0, cx(1,1))\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADEC81687F8C3", "submission_order": 3, "result": "WA", "execution_time": "1378 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n\n    qc.ch(0,1)\n\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADEC81687F8C3", "submission_order": 4, "result": "AC", "execution_time": "1499 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.ch(0,1)\n\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADEFD6DC671F1", "submission_order": 1, "result": "RE", "execution_time": "733 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "ADEFD6DC671F1", "submission_order": 2, "result": "AC", "execution_time": "809 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE12CA78084D4", "submission_order": 1, "result": "AC", "execution_time": "1063 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE1C107707B06", "submission_order": 1, "result": "RE", "execution_time": "912 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi / 3, 0)\n    qc.h(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE1C107707B06", "submission_order": 2, "result": "WA", "execution_time": "918 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi / 3, 0)\n    qc.h(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE1C107707B06", "submission_order": 3, "result": "WA", "execution_time": "855 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE1C107707B06", "submission_order": 4, "result": "AC", "execution_time": "918 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE22EFB6A58CD", "submission_order": 1, "result": "RE", "execution_time": "777 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    alpha0 = np.exp(1j * np.pi / 4)  # 例えば、45度の位相を持つ複素数\n    alpha1 = np.exp(1j * np.pi / 3)  # 例えば、60度の位相を持つ複素数\n    alpha2 = np.exp(1j * np.pi / 6)  # 例えば、30度の位相を持つ複素数\n\n\n    # 各量子ビットに対して任意の複素振幅を設定\n    qc.initialize([alpha0, alpha1, alpha2, 0], [0, 1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE22EFB6A58CD", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    alpha0 = np.exp(1j * np.pi / 4)  # 例えば、45度の位相を持つ複素数\n    alpha1 = np.exp(1j * np.pi / 3)  # 例えば、60度の位相を持つ複素数\n    alpha2 = np.exp(1j * np.pi / 6)  # 例えば、30度の位相を持つ複素数\n\n    # 各量子ビットに対して任意の複素振幅を設定\n    qc.initialize([alpha0, alpha1, alpha2, 0], [0, 1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE22EFB6A58CD", "submission_order": 3, "result": "RE", "execution_time": "774 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    alpha0 = np.exp(1j * 3.14 / 4)  # 例えば、45度の位相を持つ複素数\n    alpha1 = np.exp(1j * 3.14 / 3)  # 例えば、60度の位相を持つ複素数\n    alpha2 = np.exp(1j * 3.14 / 6)  # 例えば、30度の位相を持つ複素数\n\n    # 各量子ビットに対して任意の複素振幅を設定\n    qc.initialize([alpha0, alpha1, alpha2, 0], [0, 1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE22EFB6A58CD", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport cmath\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    # 例として、任意の複素振幅を設定\n    alpha0 = cmath.exp(1j * cmath.pi / 4)  # 例えば、45度の位相を持つ複素数\n    alpha1 = cmath.exp(1j * cmath.pi / 3)  # 例えば、60度の位相を持つ複素数\n    alpha2 = cmath.exp(1j * cmath.pi / 6)  # 例えば、30度の位相を持つ複素数\n\n    # 各量子ビットに対して任意の複素振幅を設定\n    qc.initialize([alpha0, alpha1, alpha2, 0], [0, 1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE22EFB6A58CD", "submission_order": 5, "result": "RE", "execution_time": "816 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    # 例として、任意の複素振幅を設定\n    alpha0 = ComplexNumber(0.92388, 0.38268)  # 例えば、45度の位相を持つ複素数\n    alpha1 = ComplexNumber(0.5, 0.86603)      # 例えば、60度の位相を持つ複素数\n    alpha2 = ComplexNumber(0.70711, 0.70711)  # 例えば、45度の位相を持つ複素数\n\n    # 各量子ビットに対して任意の複素振幅を設定\n    state_vector = [ComplexNumber(alpha0.real, alpha0.imag),\n                    ComplexNumber(alpha1.real, alpha1.imag),\n                    ComplexNumber(alpha2.real, alpha2.imag),\n                    ComplexNumber(0, 0)]\n    qc.initialize(state_vector, [0, 1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 1, "result": "WA", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 2, "result": "RE", "execution_time": "814 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.uc(0, 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 3, "result": "RE", "execution_time": "784 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.toffoli(0, 0, 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 4, "result": "RE", "execution_time": "757 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.toffoli(0, 1, 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 5, "result": "RE", "execution_time": "793 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.toffoli(0, 1, 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 6, "result": "RE", "execution_time": "915 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.toffoli(0, 1, 2)\n    qc.cx(2, 1)\n\n    \n\n    return qc[:2]\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 7, "result": "QLE", "execution_time": "756 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.toffoli(0, 1, 2)\n    qc.cx(2, 1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 8, "result": "RE", "execution_time": "792 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.toffoli(0, 1, 2)\n    qc.cx(2, 1)\n    qc.remove_gate(2)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 9, "result": "RE", "execution_time": "894 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qr = QuantumRegister(1)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.toffoli(0, 1, qr)\n    qc.cx(qr, 1)\n    \n\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 10, "result": "RE", "execution_time": "778 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qr = QuantumRegister(1)\n    # Write your code here:\n    qc.h(0)\n    qc.ccx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 11, "result": "RE", "execution_time": "774 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qr = QuantumRegister(1)\n    # Write your code here:\n    qc.xor(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 12, "result": "WA", "execution_time": "1609 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 13, "result": "WA", "execution_time": "821 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 14, "result": "WA", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.h(range(2))\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 15, "result": "WA", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 16, "result": "WA", "execution_time": "931 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 17, "result": "WA", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.x(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 18, "result": "WA", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 19, "result": "WA", "execution_time": "850 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.x(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 20, "result": "WA", "execution_time": "1404 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.x(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE26101434B41", "submission_order": 21, "result": "AC", "execution_time": "849 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE2F25BBB9838", "submission_order": 1, "result": "AC", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE41105C4DB03", "submission_order": 1, "result": "RE", "execution_time": "1031 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.u3(1.91,pi,0)\n    qc.swap(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE41105C4DB03", "submission_order": 2, "result": "RE", "execution_time": "742 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1).c_if(0,1).c_if(1,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE41105C4DB03", "submission_order": 3, "result": "RE", "execution_time": "762 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1).c_if(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE5171DF4BB99", "submission_order": 1, "result": "WA", "execution_time": "1014 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE5171DF4BB99", "submission_order": 2, "result": "AC", "execution_time": "1257 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE55C078822DF", "submission_order": 1, "result": "WA", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * acos(1/sqrt(3))\n    qc.h(0)\n    qc.ry(-theta, 0)\n    qc.cx(0,1)\n    qc.ry(theta, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE55C078822DF", "submission_order": 2, "result": "RE", "execution_time": "778 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2*acos(1/sqrt(3))\n    qc.cry(theta, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE55C078822DF", "submission_order": 3, "result": "WA", "execution_time": "837 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2*acos(1/sqrt(3))\n    qc.cry(theta, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE55C078822DF", "submission_order": 4, "result": "AC", "execution_time": "1444 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2*acos(1/sqrt(3))\n    qc.cry(theta, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE61ECA230463", "submission_order": 1, "result": "AC", "execution_time": "1418 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE66D12718F41", "submission_order": 1, "result": "AC", "execution_time": "1724 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE6C4C360A276", "submission_order": 1, "result": "AC", "execution_time": "922 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE7D6D9FB01E1", "submission_order": 1, "result": "AC", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE886B5E1C1CD", "submission_order": 1, "result": "WA", "execution_time": "2030 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(2):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE886B5E1C1CD", "submission_order": 2, "result": "WA", "execution_time": "1932 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AE886B5E1C1CD", "submission_order": 3, "result": "AC", "execution_time": "1969 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEA4D94633D1F", "submission_order": 1, "result": "AC", "execution_time": "1119 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 1, "result": "WA", "execution_time": "815 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cz(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 2, "result": "WA", "execution_time": "801 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cz(0, 1)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 3, "result": "WA", "execution_time": "1737 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cz(0, 1)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 4, "result": "WA", "execution_time": "1654 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cz(0, 1)\n   #qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 5, "result": "RE", "execution_time": "791 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 0)\n   #qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 6, "result": "WA", "execution_time": "1763 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n   #qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 7, "result": "WA", "execution_time": "1095 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cz(0, 1)\n   #qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 8, "result": "WA", "execution_time": "898 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cy(0, 1)\n   #qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 9, "result": "RE", "execution_time": "765 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 1)\n   #qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 10, "result": "RE", "execution_time": "1717 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(1, 1)\n   #qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 11, "result": "RE", "execution_time": "977 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 1)\n    #qc.cx(0, 1)   \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 12, "result": "WA", "execution_time": "882 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cz(0, 1)\n    #qc.cx(0, 1)   \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 13, "result": "WA", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(1)\n    #qc.cx(0, 1)   \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 14, "result": "WA", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.z(0)\n    qc.h(0)\n       #qc.cx(0, 1)   \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEBE4898F26DF", "submission_order": 15, "result": "RE", "execution_time": "734 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n   qc.cz(0, 1)\n   qc.h(0)\n       #qc.cx(0, 1)   \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AED7BF72475A8", "submission_order": 1, "result": "WA", "execution_time": "1390 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEE8F60E43E9C", "submission_order": 1, "result": "WA", "execution_time": "1759 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEE8F60E43E9C", "submission_order": 2, "result": "WA", "execution_time": "1765 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEE8F60E43E9C", "submission_order": 3, "result": "RE", "execution_time": "1632 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * np.arctan(np.sqrt(2/1)), 0)\n    qc.cry(2 * np.arctan(np.sqrt(1/1)), 0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AEE8F60E43E9C", "submission_order": 4, "result": "AC", "execution_time": "1822 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * np.arctan(np.sqrt(2/1)), 0)\n    qc.cry(2 * np.arctan(np.sqrt(1/1)), 0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF027561B7ABB", "submission_order": 1, "result": "WA", "execution_time": "2005 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF027561B7ABB", "submission_order": 2, "result": "AC", "execution_time": "1951 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF030CCB62C1B", "submission_order": 1, "result": "AC", "execution_time": "1037 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF0BC1BBA16DE", "submission_order": 1, "result": "AC", "execution_time": "859 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF12F56FE734E", "submission_order": 1, "result": "AC", "execution_time": "1685 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF24C1827BC2A", "submission_order": 1, "result": "AC", "execution_time": "929 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta_0 = math.acos(1 / math.sqrt(3))\n    theta_1 = math.pi / 2\n\n    qc.ry(theta_0, 0)\n    qc.x(0)\n    qc.cry(theta_1, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF253AF68EA2F", "submission_order": 1, "result": "AC", "execution_time": "995 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF2EDB7ED49D5", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit import Parameter\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta_0 = Parameter('theta0')\n    phi_0 = Parameter('phi0')\n    lambda_0 = Parameter('lambda0')\n\n    theta_1 = Parameter('theta1')\n    phi_1 = Parameter('phi1')\n    lambda_1 = Parameter('lambda1')\n\n    qc = QuantumCircuit(2)\n\n    qc.u3(theta_0, phi_0, lambda_0, 0)\n    qc.u3(theta_1, phi_1, lambda_1, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF5D4E9E2B36D", "submission_order": 1, "result": "WA", "execution_time": "1800 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.h(1)\n\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF5D4E9E2B36D", "submission_order": 2, "result": "WA", "execution_time": "1632 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.h(1)\n    qc.x(1)\n\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF5D4E9E2B36D", "submission_order": 3, "result": "AC", "execution_time": "1704 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF73352DB1B94", "submission_order": 1, "result": "RE", "execution_time": "763 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(1/3)) * 2\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF73352DB1B94", "submission_order": 2, "result": "AC", "execution_time": "868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(1/3)) * 2\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF7657B742268", "submission_order": 1, "result": "AC", "execution_time": "1501 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF9670B0B1BEA", "submission_order": 1, "result": "AC", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF9A0681FA9A3", "submission_order": 1, "result": "WA", "execution_time": "1841 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(range(2))\n    qc.z(1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF9A0681FA9A3", "submission_order": 2, "result": "WA", "execution_time": "847 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)  \n    \n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AF9E36AF2AD74", "submission_order": 1, "result": "AC", "execution_time": "1557 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFA047D4E62D7", "submission_order": 1, "result": "AC", "execution_time": "1387 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFA94076241C0", "submission_order": 1, "result": "WA", "execution_time": "1742 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFA94076241C0", "submission_order": 2, "result": "AC", "execution_time": "1295 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFBCCB7177BB7", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Initialize\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(4)\n\n    # Example amplitudes (normalize them)\n    a0, a1, a2 = 0.5, 0.5, 0.70710678\n    norm = np.sqrt(abs(a0)**2 + abs(a1)**2 + abs(a2)**2)\n    a0, a1, a2 = a0/norm, a1/norm, a2/norm\n\n    # Target vector [a0, a2, a1, 0] in basis order\n    vec = [a0, a2, a1, 0]\n\n    init = Initialize(vec)\n\n    qc.append(init, [0, 1])  # first |ψ⟩\n    qc.append(init, [2, 3])  # second |ψ⟩\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFBCCB7177BB7", "submission_order": 2, "result": "AC", "execution_time": "1500 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFBF0148A20C4", "submission_order": 1, "result": "AC", "execution_time": "1695 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFD250B28BD31", "submission_order": 1, "result": "AC", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(1,0)\n    qc.ry(0.1,1)\n    qc.cnot(0,1)\n    qc.ry(-0.1,1)\n    qc.cnot(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFDFF5FD0C30A", "submission_order": 1, "result": "RE", "execution_time": "1774 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A4", "user": "AFDFF5FD0C30A", "submission_order": 2, "result": "WA", "execution_time": "1860 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A4", "user": "AFDFF5FD0C30A", "submission_order": 3, "result": "AC", "execution_time": "1848 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A4", "user": "AFE8E6434991E", "submission_order": 1, "result": "AC", "execution_time": "2037 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0),\n    qc.ch(0,1),\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFED52EC8535A", "submission_order": 1, "result": "WA", "execution_time": "816 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ry(0.5, 0)\n    qc.ry(0.5, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFED52EC8535A", "submission_order": 2, "result": "WA", "execution_time": "814 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ry(1.57, 0)\n    qc.ry(1.57, 1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFED52EC8535A", "submission_order": 3, "result": "RE", "execution_time": "826 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ry(np.pi/2, 0)\n    qc.ry(np.pi/2, 1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 1, "result": "RE", "execution_time": "748 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    alpha_1 = 0.5\n    qc.u1(alpha_1, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 2, "result": "RE", "execution_time": "770 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    a0, a1, a2 = 0.5, 0.3, 0.8\n    qc.u3(2 * a0, 0, 0, 0)  # a0を適用\n    qc.u3(2 * a1, 0, 0, 1)  # a1を適用\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 3, "result": "RE", "execution_time": "870 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.initialize([1, 0, 0], 0)\n    qc.initialize([0, 1, 0], 1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 4, "result": "UGE", "execution_time": "784 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.initialize([1, 0], 0)\n    qc.initialize([0, 1], 1)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 5, "result": "WA", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.h(1)\n    qc.cz(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 6, "result": "WA", "execution_time": "824 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    theta = 0.5\n    qc.rz(theta, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 7, "result": "WA", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    theta = 0.5\n    qc.rz(theta, 0)\n    qc.rz(theta, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 8, "result": "WA", "execution_time": "829 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    theta = 0.5\n    qc.rz(theta, 0)\n    qc.rz(theta, 1)\n    qc.x(1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 9, "result": "WA", "execution_time": "1291 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta_0 = 0.1\n    theta_1 = 0.2\n    theta_2 = 0.3\n    \n    qc.ry(theta_0, 0)\n    qc.ry(theta_1, 1)\n    \n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 10, "result": "WA", "execution_time": "1970 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.z(1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 11, "result": "WA", "execution_time": "1116 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.sdg(0)\n    qc.h(1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 12, "result": "WA", "execution_time": "811 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cp(2 * 3.141592653589793 / 3, 0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 13, "result": "WA", "execution_time": "1621 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n\n    qc.x(1)\n\n    qc.h(1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 14, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 15, "result": "RE", "execution_time": "1893 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.ccx(0, 1, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 16, "result": "RE", "execution_time": "910 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1).c_if(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF6FE1A832BA", "submission_order": 17, "result": "AC", "execution_time": "1716 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF7780063E35", "submission_order": 1, "result": "WA", "execution_time": "1226 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFF7780063E35", "submission_order": 2, "result": "AC", "execution_time": "1272 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # 最初の量子ビットを状態 |+⟩ にする\n    qc.h(0)\n    \n    # 制御されたY回転を使って振幅を調整し、重ね合わせを作成する\n    theta = 2 * np.arccos(1/np.sqrt(3))\n    qc.cry(theta, 0, 1)\n    \n    # Toffoli（CCX）ゲートを使用して最後の振幅を調整（状態 |11⟩ を |01⟩ に変換）\n    qc.cx(0, 1)\n    \n    # この時点で量子回路は次の状態になっている\n    # (1/√3)(|00⟩ + |01⟩ + |10⟩)\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 2, "result": "WA", "execution_time": "940 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    # Create a quantum circuit with 2 qubits\n    qc = QuantumCircuit(2)\n    \n    # Apply Hadamard gate to qubit 0 to create an equal superposition of |0> and |1>\n    qc.h(0) # This creates the state (|0> + |1>) for qubit 0\n    \n    # Apply a controlled NOT gate (CNOT) with qubit 0 as control and qubit 1 as target\n    qc.cx(0, 1)\n    \n    # Apply rotation to undo the effect of cx on |11>\n    qc.ry(-2 * sqrt(2)/sqrt(3), 1)\n    \n    # Apply a controlled Y-rotation to create the state (|00> + |01> + |10>)/sqrt(3), ignoring global phase\n    qc.cry(2 * sqrt(2)/sqrt(3), 0, 1)\n    \n    # Apply extra gates to balance global phase, if necessary (problem statement omits requirement)\n    \n    # Return the quantum circuit\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 3, "result": "RE", "execution_time": "765 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U3Gate\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply H gate to qubit 0 to get (|0> + |1>)/sqrt(2)\n    qc.h(0)\n    \n    # Apply U3 gate to qubit 0 to adjust amplitude from 1/sqrt(2) to 1/sqrt(3)\n    theta = 2 * acos(sqrt(2/3))\n    qc.u3(theta, 0, 0, 0)\n    \n    # Controlled-U3 operation with angle to get 1/sqrt(3) amplitude for |01>\n    # Since qubit 1 is our target, we invert our control and target for CU3\n    qc.x(0)\n    qc.cu3(2*acos(1/sqrt(3)), 0, 0, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 4, "result": "RE", "execution_time": "758 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U3Gate\nfrom math import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply H gate to qubit 0 to get (|0> + |1>)/sqrt(2)\n    qc.h(0)\n    \n    # Apply U3 gate to qubit 0 to adjust amplitude from 1/sqrt(2) to 1/sqrt(3)\n    theta = 2 * acos(sqrt(2/3))\n    qc.u3(theta, 0, 0, 0)\n    \n    # Controlled-U3 operation with angle to get 1/sqrt(3) amplitude for |01>\n    # Since qubit 1 is our target, we invert our control and target for CU3\n    qc.x(0)\n    qc.cu3(2*acos(1/sqrt(3)), 0, 0, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U3Gate\nfrom math import sqrt, arccos as acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply H gate to qubit 0 to get (|0> + |1>)/sqrt(2)\n    qc.h(0)\n    \n    # Apply U3 gate to qubit 0 to adjust amplitude from 1/sqrt(2) to 1/sqrt(3)\n    theta = 2 * acos(sqrt(2/3))\n    qc.u3(theta, 0, 0, 0)\n    \n    # Controlled-U3 operation with angle to get 1/sqrt(3) amplitude for |01>\n    # Since qubit 1 is our target, we invert our control and target for CU3\n    qc.x(0)\n    qc.cu3(2*acos(1/sqrt(3)), 0, 0, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 6, "result": "RE", "execution_time": "1086 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U3Gate\nfrom math import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply H gate to qubit 0 to get (|0> + |1>)/sqrt(2)\n    qc.h(0)\n    \n    # Apply U3 gate to qubit 0 to adjust amplitude from 1/sqrt(2) to 1/sqrt(3)\n    theta = 2 * acos(sqrt(2/3))\n    qc.u3(theta, 0, 0, 0)\n    \n    # Controlled-U3 operation with angle to get 1/sqrt(3) amplitude for |01>\n    # Since qubit 1 is our target, we invert our control and target for CU3\n    qc.x(0)\n    qc.cu3(2*acos(1/sqrt(3)), 0, 0, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 7, "result": "RE", "execution_time": "811 ms", "memory": "79 MiB", "code": "'''python\nfrom math import sqrt\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT  # QFT is not used in this problem but included due to unclear wording\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Initialize amplitudes\n    amplitude = 1 / sqrt(3)\n    \n    # Apply a Hadamard gate to the first qubit to create a superposition\n    qc.h(0)  # This creates the state (|0⟩ + |1⟩) / sqrt(2) for the first qubit\n    # Now we need to adjust the first qubit's probabilities to create the state (2|0⟩ + |1⟩) / sqrt(3)\n    # We can apply a controlled rotation to achieve this\n    angle = 2 * acos(sqrt(2/3))  # Calculate the required rotation angle\n    qc.cry(angle, 0, 1)  # Apply controlled rotation to the second qubit\n    qc.cx(0, 1)  # Use the first qubit to control the NOT gate on the second qubit\n    qc.x(0)  # Apply a NOT gate to the first qubit to create the state |10⟩\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 8, "result": "WA", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # 3つの状態の重ね合わせで、それぞれの振幅が1/sqrt(3)\n    # |0⟩(|00⟩)の振幅は既に1なので変更不要。\n    \n    # |1⟩(|10⟩)の振幅を設定するために、制御NOTを1量子ビット目に適用\n    qc.cx(0, 1)\n    qc.ry(2 * acos(1 / sqrt(3)), 0)  # Y軸周りの回転で振幅を調整\n    qc.cx(0, 1)\n    \n    # |2⟩(|01⟩)の振幅を設定するために、必要な操作を適用\n    qc.x(0)  # |00⟩の状態を反転して|01⟩にする\n    qc.ry(2 * acos(1 / sqrt(3)), 1)  # Y軸周りの回転で振幅を調整\n    qc.x(0)  # |01⟩の状態を|00⟩に戻す\n    \n    return qc\n'''"}
{"problem": "QPC001_A4", "user": "AFFB41A6CC610", "submission_order": 9, "result": "AC", "execution_time": "996 ms", "memory": "90 MiB", "code": "'''python\nfrom math import sqrt, acos\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * acos(sqrt(1/3))\n    theta2 = 2 * acos(sqrt(1/2))\n\n    qc.ry(theta, 0)\n    qc.cry(theta2, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 1, "result": "WA", "execution_time": "1508 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.p(2 * acos(sqrt(2) / sqrt(3)), 0)\n    qc.h(1)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 2, "result": "WA", "execution_time": "933 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.p(2 * acos(sqrt(2) / sqrt(3)), 0)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 3, "result": "WA", "execution_time": "1032 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(2 * acos(sqrt(2) / sqrt(3)), 0)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 4, "result": "WA", "execution_time": "904 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    t = 4 * math.atan(math.sqrt(3) / (3 + math.sqrt(6)))\n    qc.ry(t, 0)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 5, "result": "WA", "execution_time": "930 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    t = 4 * math.acos(math.sqrt(2) / math.sqrt(3))\n    qc.ry(t, 0)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 6, "result": "WA", "execution_time": "1013 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    t = 4 * math.acos(math.sqrt(2) / math.sqrt(3))\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 7, "result": "WA", "execution_time": "867 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    t = 2 * math.acos(math.sqrt(2) / math.sqrt(3))\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 8, "result": "WA", "execution_time": "898 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    t = 2 * math.acos(math.sqrt(2) / math.sqrt(3))\n    qc.ry(t, 1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 9, "result": "WA", "execution_time": "1013 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    t = 2 * math.acos(math.sqrt(2) / math.sqrt(3))\n    qc.ry(t, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 10, "result": "WA", "execution_time": "837 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    t = 2 * math.acos(math.sqrt(2) / math.sqrt(3))\n    qc.ry(t, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A008EACC8CBD2", "submission_order": 11, "result": "AC", "execution_time": "880 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    t = 2 * math.acos(math.sqrt(2) / math.sqrt(3))\n    qc.ry(t, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A00E339720B8B", "submission_order": 1, "result": "AC", "execution_time": "851 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.r(2*math.acos(1.0/math.sqrt(3.0)), math.pi/2, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A01C63C44D3F0", "submission_order": 1, "result": "AC", "execution_time": "1748 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    # Write your code here:\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A030D9153F793", "submission_order": 1, "result": "WA", "execution_time": "1385 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos,sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*acos(1/sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A030D9153F793", "submission_order": 2, "result": "RE", "execution_time": "1389 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos,sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*asin(1/sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A030D9153F793", "submission_order": 3, "result": "AC", "execution_time": "1349 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos,sqrt,asin\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*asin(1/sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A037BAC5FB21E", "submission_order": 1, "result": "WA", "execution_time": "1459 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A037BAC5FB21E", "submission_order": 2, "result": "WA", "execution_time": "962 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A037BAC5FB21E", "submission_order": 3, "result": "WA", "execution_time": "2000 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A037BAC5FB21E", "submission_order": 4, "result": "AC", "execution_time": "1151 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.z(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0428DCD513C7", "submission_order": 1, "result": "WA", "execution_time": "1698 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = math.atan(math.sqrt(2))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0428DCD513C7", "submission_order": 2, "result": "AC", "execution_time": "1664 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * math.atan(math.sqrt(2))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A043C9B42F9EC", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nimport \nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi / 2 - math.asin(1/3), 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A043C9B42F9EC", "submission_order": 2, "result": "WA", "execution_time": "1375 ms", "memory": "141 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi / 2 - math.asin(1/3), 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A043C9B42F9EC", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport mat\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi - math.acos(1/3), 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A043C9B42F9EC", "submission_order": 4, "result": "AC", "execution_time": "1361 ms", "memory": "141 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi - math.acos(1/3), 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A055731ED896A", "submission_order": 1, "result": "RE", "execution_time": "1410 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=2*math.acos(1/sqrt(3))\n    qc.rx(t,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A055731ED896A", "submission_order": 2, "result": "WA", "execution_time": "1495 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=2*math.acos(1/math.sqrt(3))\n    qc.rx(t,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A055731ED896A", "submission_order": 3, "result": "AC", "execution_time": "1463 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=4*math.atan(math.sqrt(6)/(math.sqrt(3)+3))\n    qc.ry(t,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A05628D8A0F32", "submission_order": 1, "result": "AC", "execution_time": "1355 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = math.atan(math.sqrt(2))\n    qc.ry(2*theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0583B402EF0F", "submission_order": 1, "result": "RE", "execution_time": "1435 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.cx(0,1)\n    qc.ry(theta,1)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A05CFFBAC6F97", "submission_order": 1, "result": "AC", "execution_time": "1387 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*np.arccos(1/np.sqrt(3)),0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A08525A55A31C", "submission_order": 1, "result": "RE", "execution_time": "1767 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.p(math.asin(1/math.sqrt(3),0),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A08525A55A31C", "submission_order": 2, "result": "WA", "execution_time": "1793 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.p(math.asin(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A08525A55A31C", "submission_order": 3, "result": "WA", "execution_time": "1901 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.p(math.acos(1/math.sqrt(3),),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A08525A55A31C", "submission_order": 4, "result": "WA", "execution_time": "1929 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rz(math.asin(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A08525A55A31C", "submission_order": 5, "result": "WA", "execution_time": "1873 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.asin(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A08525A55A31C", "submission_order": 6, "result": "WA", "execution_time": "1822 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A08525A55A31C", "submission_order": 7, "result": "AC", "execution_time": "1826 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.asin(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0893B06B88B3", "submission_order": 1, "result": "WA", "execution_time": "988 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply a Hadamard gate to the first qubit\n    qc.h(0)\n\n    # Apply a CNOT gate with the first qubit as control and the second as target\n    qc.cx(0, 1)\n\n    # Manipulate the probabilities to remove |11> state\n    # This might involve applying additional gates and requires careful design\n    # One possible way is to apply a controlled Z gate with a phase shift\n    qc.cz(0,1)\n    qc.p(-math.pi/2, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0893B06B88B3", "submission_order": 2, "result": "AC", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2*math.atan(-(math.sqrt(2)-1)/(math.sqrt(2)+1))\n    # Apply a Hadamard gate to the first qubit\n    qc.h(0)\n    qc.ry(theta,0)\n    qc.h(1)\n    qc.ch(0,1)\n    #qc.ry(math.pi/2,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09A98C8543E0", "submission_order": 1, "result": "RE", "execution_time": "1859 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09A98C8543E0", "submission_order": 2, "result": "AC", "execution_time": "1949 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09BB609129DA", "submission_order": 1, "result": "WA", "execution_time": "1993 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(math.acos(1/3),0)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09BB609129DA", "submission_order": 2, "result": "WA", "execution_time": "1870 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(2*math.acos(1/3),0)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09BB609129DA", "submission_order": 3, "result": "AC", "execution_time": "1977 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09F4EBE0761A", "submission_order": 1, "result": "WA", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.r(math.pi/4, math.pi/2, 0)\n    qc.u(1.23, 0, 0, 1)\n    qc.cx(0,1)\n    qc.r(math.pi/4, math.pi/2, 0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09F4EBE0761A", "submission_order": 2, "result": "RE", "execution_time": "795 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    initial_state = np.array([1, 1, 1, 0], dtype=float)\n    initial_state /= np.linalg.norm(initial_state)\n    qc.initialize(initial_state)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09F4EBE0761A", "submission_order": 3, "result": "WA", "execution_time": "842 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(math.pi/2,0,0,0)\n    qc.u(math.pi/2,0,0,1)\n    qc.cx(1,0)\n    qc.u(0,0,0,0)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09F4EBE0761A", "submission_order": 4, "result": "WA", "execution_time": "1041 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(math.pi/4,0,0,0)\n    qc.u(1.23,0,0,1)\n    qc.cx(1,0)\n    qc.u(math.pi/4,0,0,0)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09F4EBE0761A", "submission_order": 5, "result": "RE", "execution_time": "751 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(2*math.acos(1/np.sqrt(3)),0,0,0)\n    qc.u(0,0,-math.pi/2,1)\n    qc.cx(0,1)\n    qc.u(math.pi/4,0,-math.pi/2,1)\n    qc.cx(0,1)\n    qc.u(math.pi,0,-math.pi/2,0)\n    qc.u(math.pi/4,0,math.pi,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09F4EBE0761A", "submission_order": 6, "result": "WA", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import CHGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.append(CHGate(ctrl_state=0),[0,1])\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A09F4EBE0761A", "submission_order": 7, "result": "AC", "execution_time": "847 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import CHGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0AFCAA29C4F6", "submission_order": 1, "result": "UGE", "execution_time": "797 ms", "memory": "78 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    desired_vector = [\n        1/ math.sqrt(3),\n        1/ math.sqrt(3),\n        1/ math.sqrt(3),\n        0,\n    ]\n    qc.initialize(desired_vector)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0AFCAA29C4F6", "submission_order": 2, "result": "WA", "execution_time": "1633 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(2./3.))*2.0\n    qc.h(0)\n    qc.rx(theta=theta, qubit=1)\n    qc.x(1)\n    qc.crx(theta, 1, 0)\n    qc.x(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0AFCAA29C4F6", "submission_order": 3, "result": "WA", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(2./3.))*2.0\n    qc.h(0)\n    qc.x(0)\n    qc.crx(-theta, 0, 1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0AFCAA29C4F6", "submission_order": 4, "result": "WA", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(2./3.))*2.0\n    qc.rx(theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0AFCAA29C4F6", "submission_order": 5, "result": "WA", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(2./3.))*2.0\n    qc.rx(-theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0AFCAA29C4F6", "submission_order": 6, "result": "AC", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(2./3.))*2.0\n    qc.ry(theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0C53DE0AFD8E", "submission_order": 1, "result": "RE", "execution_time": "764 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    qc = qc*\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0C53DE0AFD8E", "submission_order": 2, "result": "AC", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0C7370DDB7F5", "submission_order": 1, "result": "RE", "execution_time": "884 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    # 00 10\n    # 00 の割合多くしたいね\n    print(atan((2*sqrt(3)-3) / (3+sqrt(6))*4))\n    qc.ry(atan(0.35),0)\n    ## 00 -> 01 or 10\n    # 0.7 0.5 0.5 0\n    qc.ch(0,1)\n    qc.cx(1, 0)\n    #qc.rx(np.pi/ 2,0)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0C7370DDB7F5", "submission_order": 2, "result": "WA", "execution_time": "992 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n\n    qc.ry(atan(0.35),0)\n    ## 00 -> 01 or 10\n    # 0.7 0.5 0.5 0\n    qc.ch(0,1)\n    qc.cx(1, 0)\n    #qc.rx(np.pi/ 2,0)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0C7370DDB7F5", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ata\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n\n    qc.ry(atan(0.353555),0)\n    ## 00 -> 01 or 10\n    # 0.7 0.5 0.5 0\n    qc.ch(0,1)\n    qc.cx(1, 0)\n    #qc.rx(np.pi/ 2,0)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0C7370DDB7F5", "submission_order": 4, "result": "AC", "execution_time": "943 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n\n    qc.ry(atan(0.353555),0)\n    ## 00 -> 01 or 10\n    # 0.7 0.5 0.5 0\n    qc.ch(0,1)\n    qc.cx(1, 0)\n    #qc.rx(np.pi/ 2,0)\n    \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0D577273E1EC", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from qiskit.circuit.library.standard_gates import HGate\n \n    qc.u(-np.arcsin(np.sqrt(2)/np.sqrt(3))*2,np.pi,0,0)\n    c3h_gate = HGate().control(1)\n    qc.append(c3h_gate,[0,1])\n    qc.cnot(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0D577273E1EC", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from qiskit.circuit.library.standard_gates import HGate\n \n    qc.u(-np.arcsin(np.sqrt(2)/np.sqrt(3))*2,np.pi,0,0)\n    c3h_gate = HGate().control(1)\n    qc.append(c3h_gate,[0,1])\n    qc.cnot(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0D577273E1EC", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from qiskit.circuit.library.standard_gates import HGate\n \n    qc.u(-math.asin(math.sqrt(2)/math.sqrt(3))*2,math.pi,0,0)\n    c3h_gate = HGate().control(1)\n    qc.append(c3h_gate,[0,1])\n    qc.cnot(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0D577273E1EC", "submission_order": 4, "result": "AC", "execution_time": "878 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import HGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n \n    qc.u(-math.asin(math.sqrt(2)/math.sqrt(3))*2,math.pi,0,0)\n    c3h_gate = HGate().control(1)\n    qc.append(c3h_gate,[0,1])\n    qc.cnot(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0DBF46211CF6", "submission_order": 1, "result": "AC", "execution_time": "1572 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2*atan(sqrt(2))\n\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    # qc.remove_final_measurements()  # no measurements allowed\n    # from qiskit.quantum_info import Statevector\n    # statevector = Statevector(qc)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0DECD32B88B3", "submission_order": 1, "result": "AC", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    \n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A0FFC97BD6028", "submission_order": 1, "result": "AC", "execution_time": "1640 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(1/3)), 0)\n    qc.cry(math.pi/2, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A113DEC9973D3", "submission_order": 1, "result": "WA", "execution_time": "1783 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta=math.atan(math.sqrt(2))\n    qc.rx(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A113DEC9973D3", "submission_order": 2, "result": "WA", "execution_time": "1816 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta=math.degrees(math.atan(math.sqrt(2)))\n    qc.rx(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A113DEC9973D3", "submission_order": 3, "result": "AC", "execution_time": "1805 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta=math.atan(math.sqrt(2))\n    qc.ry(2*theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A11804C9028AC", "submission_order": 1, "result": "WA", "execution_time": "1671 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    p=math.pi\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(2*p/3,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A11804C9028AC", "submission_order": 2, "result": "WA", "execution_time": "1656 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    p=math.pi\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A11804C9028AC", "submission_order": 3, "result": "AC", "execution_time": "1749 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    p=math.pi\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A11AD7307BC3D", "submission_order": 1, "result": "AC", "execution_time": "1483 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(np.arctan(np.sqrt(2))*2, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A11CAFB8F38DF", "submission_order": 1, "result": "WA", "execution_time": "1560 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(math.pi/1.644,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A11CAFB8F38DF", "submission_order": 2, "result": "AC", "execution_time": "1509 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(math.pi/1.644270554,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 1, "result": "WA", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 2, "result": "WA", "execution_time": "949 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    PI = 3.14159265358979323846264338\n    qc.ry(PI*2/3,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 3, "result": "WA", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.radians(120),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 4, "result": "WA", "execution_time": "901 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(math.radians(120),0,0,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 5, "result": "WA", "execution_time": "954 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(math.sqrt(2/3))\n    qc.u(theta,0,0,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 6, "result": "WA", "execution_time": "1089 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.radians(120),0)\n    qc.rx(math.radians(45),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 7, "result": "WA", "execution_time": "888 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(2 * -0.7297, 0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 8, "result": "RE", "execution_time": "769 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.(math.radians(120),0,math.radians(180),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 9, "result": "RE", "execution_time": "743 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.(math.radians(90),0,math.radians(180),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 10, "result": "WA", "execution_time": "832 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(math.radians(120),0,math.radians(180),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 11, "result": "WA", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(math.radians(120),math.radians(45),math.radians(180),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 12, "result": "WA", "execution_time": "1453 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(math.radians(30),0,math.radians(180),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 13, "result": "WA", "execution_time": "827 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(math.radians(30),math.radians(30),math.radians(180),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 14, "result": "WA", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(math.radians(30),math.radians(30),0,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 15, "result": "WA", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(0,math.radians(30),0,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 16, "result": "WA", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(math.radians(30),0,0,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 17, "result": "WA", "execution_time": "936 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(0,0,math.radians(30),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 18, "result": "WA", "execution_time": "958 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(0,math.radians(30),math.radians(30),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 19, "result": "WA", "execution_time": "1653 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(math.radians(30),0,math.radians(30),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 20, "result": "WA", "execution_time": "878 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0);\n    qc.u(math.radians(30),math.radians(30),0,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 21, "result": "WA", "execution_time": "1471 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.radians(120),0)\n    qc.rz(math.radians(120),0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 22, "result": "WA", "execution_time": "906 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * math.asin(math.sqrt(1/3))\n    qc.rx(angle, 0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 23, "result": "WA", "execution_time": "900 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * math.asin(math.sqrt(2/3))\n    qc.rx(angle, 0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12C7501682B3", "submission_order": 24, "result": "WA", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * math.asin(math.sqrt(2/3))\n    qc.rz(angle, 0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12F48F2106E2", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.atan(math.sqrt(2)))\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12F48F2106E2", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.atan(math.sqrt(2)),0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12F48F2106E2", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2*math.atan(math.sqrt(2))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A12F48F2106E2", "submission_order": 4, "result": "AC", "execution_time": "1083 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2*math.atan(math.sqrt(2))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1321E7D1E127", "submission_order": 1, "result": "RE", "execution_time": "779 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(2))\n    qc.ry(theta, 0)\n    qc.ch(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1321E7D1E127", "submission_order": 2, "result": "AC", "execution_time": "993 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(2))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A15C3D72CEF92", "submission_order": 1, "result": "AC", "execution_time": "1480 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * math.atan(2 ** 0.5)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A175E9FE2FB63", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqr\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n theta = 2 * acos(1/sqrt(3))\n    qc.ry(theta, 0)  # Ryゲートで |00⟩, |10⟩ の重ね合わせを作る\n\n    # 量子ビット1に対しても同様の回転ゲートを適用\n    qc.ry(theta, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A175E9FE2FB63", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqr\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * acos(1/sqrt(3))\n    qc.ry(theta, 0)  # Ryゲートで適切な重ね合わせを作成\n\n    # 量子ビット1に対しても同様の回転ゲートを適用\n    qc.ry(theta, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A175E9FE2FB63", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqr\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.23096, 0)  # 1.23096 ≒ 2*acos(2/3)\n\n    # 量子ビット1に適切なRyを適用\n    qc.ry(1.23096, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A175E9FE2FB63", "submission_order": 4, "result": "WA", "execution_time": "1510 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.23096, 0)  # 1.23096 ≒ 2*acos(2/3)\n\n    # 量子ビット1に適切なRyを適用\n    qc.ry(1.23096, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1789A21A2F3A", "submission_order": 1, "result": "WA", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1789A21A2F3A", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1789A21A2F3A", "submission_order": 3, "result": "AC", "execution_time": "914 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A18008DC3F6EC", "submission_order": 1, "result": "WA", "execution_time": "811 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A18008DC3F6EC", "submission_order": 2, "result": "RE", "execution_time": "746 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.u(-math.pi*2/3, 0, 0)(0)\n    qc.ch(0, 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A18008DC3F6EC", "submission_order": 3, "result": "RE", "execution_time": "868 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.u(-math.pi*2/3, 0, 0)\n    qc.ch(0, 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A18008DC3F6EC", "submission_order": 4, "result": "RE", "execution_time": "781 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.u(-math.pi*2/3, 0, 0)\n    qc.ch(0, 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A18008DC3F6EC", "submission_order": 5, "result": "WA", "execution_time": "1440 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cu((2.0/3.0)**(0.5), 0, 0, 0, 0, 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.x(1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A18008DC3F6EC", "submission_order": 6, "result": "RE", "execution_time": "812 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cu(math.arcsin((2.0/3.0)**(0.5)), 0, 0, 0, 0, 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.x(1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A18008DC3F6EC", "submission_order": 7, "result": "WA", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cu(math.asin((2.0/3.0)**(0.5)), 0, 0, 0, 0, 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.x(1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A185F9D1BB896", "submission_order": 1, "result": "RE", "execution_time": "726 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np.\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(np.pi / 3.0, 0)\n    qc.cry(np.pi / 3.0, 0 ,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A185F9D1BB896", "submission_order": 2, "result": "RE", "execution_time": "805 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np.\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * np.pi / 3.0, 0)\n    qc.cry(2 * np.pi / 3.0, 0 ,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A185F9D1BB896", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * np.arccos(1/np.sqrt(3))\n    qc.ry(angle, 0)\n    qc.cry(np.pi/2, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A185F9D1BB896", "submission_order": 4, "result": "RE", "execution_time": "1125 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * math.arccos(1/np.sqrt(3))\n    qc.ry(angle, 0)\n    qc.cry(np.pi/2, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A185F9D1BB896", "submission_order": 5, "result": "RE", "execution_time": "811 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * math.acos(1/np.sqrt(3))\n    qc.ry(angle, 0)\n    qc.cry(np.pi/2, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A185F9D1BB896", "submission_order": 6, "result": "RE", "execution_time": "1007 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * math.acos(1/math.sqrt(3))\n    qc.ry(angle, 0)\n    qc.cry(np.pi/2, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A185F9D1BB896", "submission_order": 7, "result": "WA", "execution_time": "813 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * math.acos(1/math.sqrt(3))\n    qc.ry(angle, 0)\n    qc.cry(math.pi/2, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A185F9D1BB896", "submission_order": 8, "result": "AC", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * math.asin(1/math.sqrt(3))\n    qc.ry(angle, 1)\n    qc.cry(math.pi/2, 1, 0, ctrl_state=0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A198D726C71CA", "submission_order": 1, "result": "RE", "execution_time": "1439 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.atan(math.sqrt(2)),0)\n    ch(0,1)\n    cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A198D726C71CA", "submission_order": 2, "result": "AC", "execution_time": "1569 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.atan(math.sqrt(2)),0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1B420D3492F4", "submission_order": 1, "result": "AC", "execution_time": "782 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1DA197CA4778", "submission_order": 1, "result": "AC", "execution_time": "837 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),1)\n\n    qc.x(1)\n\n    qc.ch(1,0)\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1DAE8F1E18E5", "submission_order": 1, "result": "RE", "execution_time": "2128 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6) / (3.0 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1DAE8F1E18E5", "submission_order": 2, "result": "AC", "execution_time": "2110 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6) / (3.0 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1DB882EDCE64", "submission_order": 1, "result": "WA", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1E331661EE9E", "submission_order": 1, "result": "WA", "execution_time": "1613 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1E331661EE9E", "submission_order": 2, "result": "AC", "execution_time": "1827 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A1FD000811331", "submission_order": 1, "result": "WA", "execution_time": "896 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(100):\n        qc.h(0)\n        qc.ch(0,1)\n        qc.cx(1,0)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A21D13B956ACC", "submission_order": 1, "result": "AC", "execution_time": "1145 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2258F4C760B5", "submission_order": 1, "result": "AC", "execution_time": "1523 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.acos(math.sqrt(2)/math.sqrt(3)), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A242E2B9E1247", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import arctan, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 4.0 * atan(sqrt(6) / (3 + sqrt(3)))\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A242E2B9E1247", "submission_order": 2, "result": "RE", "execution_time": "1582 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 4.0 * artan(sqrt(6) / (3 + sqrt(3)))\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A242E2B9E1247", "submission_order": 3, "result": "AC", "execution_time": "1607 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 4.0 * atan(sqrt(6) / (3 + sqrt(3)))\n    qc.ry(t, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 1, "result": "WA", "execution_time": "860 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 2, "result": "WA", "execution_time": "805 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 3, "result": "RE", "execution_time": "773 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h()\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 4, "result": "WA", "execution_time": "1377 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 5, "result": "WA", "execution_time": "976 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 6, "result": "RE", "execution_time": "745 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt\n    init_state = [sqrt(3)/sqrt(2), 0, 0, 0]\n    qc.initialize(int_state, 0, 1)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 7, "result": "RE", "execution_time": "805 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt\n    init_state = [sqrt(3)/sqrt(2), 0, 0, 0]\n    qc.initialize(int_state, [0, 1])\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 8, "result": "RE", "execution_time": "744 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt\n    init_state = [sqrt(3)*sqrt(2), 0, 0, 0]\n    qc.initialize(int_state, [0, 1])\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 9, "result": "RE", "execution_time": "758 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt\n    init_state = [sqrt(3)*sqrt(2), 0, 0, 0]\n    qc.initialize(int_state, 0, 1)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 10, "result": "RE", "execution_time": "835 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt\n    init_state = [sqrt(3)*sqrt(4), 0, 0, 0]\n    qc.initialize(int_state, 0, 1)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 11, "result": "RE", "execution_time": "815 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt\n    init_state = [sqrt(3)*2, 0, 0, 0]\n    qc.initialize(int_state, 0, 1)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 12, "result": "RE", "execution_time": "1352 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt\n    init_state = [sqrt(3)*2, 0, 0, 0]\n    qc.initialize(int_state, 0, 1)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A24F527275A7D", "submission_order": 13, "result": "RE", "execution_time": "1566 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt\n    init_state = [sqrt(3)*2, 0, 0, 0]\n    qc.initialize(int_state, 0, 1)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A250AAD4B3168", "submission_order": 1, "result": "RE", "execution_time": "1779 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cry(pi/2, 1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A250AAD4B3168", "submission_order": 2, "result": "RE", "execution_time": "1856 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.h(0)\n    qc.cry(pi/2, 1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A250AAD4B3168", "submission_order": 3, "result": "WA", "execution_time": "1850 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    qc.ry(acos(1/sqrt(2)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A250AAD4B3168", "submission_order": 4, "result": "WA", "execution_time": "1932 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    qc.ry(acos(1/sqrt(2))/2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A250AAD4B3168", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    qc.ry(2*math.acos(1/math.sqrt(2)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A250AAD4B3168", "submission_order": 6, "result": "WA", "execution_time": "1909 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    qc.ry(2*math.acos(1/math.sqrt(2)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A250AAD4B3168", "submission_order": 7, "result": "WA", "execution_time": "1879 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    qc.ry(2*acos(1/(2**(1/2))), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A250AAD4B3168", "submission_order": 8, "result": "AC", "execution_time": "1928 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    qc.ry(2*acos(1/(3**(1/2))), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2563E02B1337", "submission_order": 1, "result": "RE", "execution_time": "950 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cz(0, 1)\n    qc.ry(-2 * np.arccos(1 / np.sqrt(3)), 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2563E02B1337", "submission_order": 2, "result": "WA", "execution_time": "828 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cz(0, 1)\n    qc.ry(-2 * math.acos(1 / math.sqrt(3)), 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2563E02B1337", "submission_order": 3, "result": "AC", "execution_time": "941 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * math.acos(math.sqrt(2/3))\n\n    qc.ry(theta, 1)\n\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A25A6CC193C44", "submission_order": 1, "result": "WA", "execution_time": "837 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A27416EAE4E1A", "submission_order": 1, "result": "AC", "execution_time": "1426 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n\n    prob_amp = math.sqrt(1 / 3)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 0, 1)\n    qc.cx(1, 0)\n\n    prob_amp = math.sqrt(1 / 2)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 1, 0)\n\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A27EDFC756146", "submission_order": 1, "result": "RE", "execution_time": "763 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    lis = []\n    k = 3\n    tmp = 0\n    while(k>0):\n        if k%2:\n            lis = lis + [tmp]\n        tmp += 1\n        k = k //2\n    m = 2 ** (lis[0])\n    \n    for i in range(1,len(lis)):\n        qc.x(lis[i])\n    if lis[0] > 0:\n        for i in range(lis[0]):\n            qc.h(i)\n    qc.ry(-2*math.acos(math.sqrt(m / 3)), lis[1])\n    qc.x(lis[1])\n    for i in range(lis[0],lis[1]):\n        qc.ch(lis[1], i)\n    qc.x(lis[1])        \n    for i in range(1,len(lis) - 1):\n        qc.x(lis[i]) \n        qc.cry(-2 * math.acos(math.sqrt(2 ** lis[i] / (3 - m))), lis[i], lis[i+1])\n        qc.x(lis[i])\n        qc.x(lis[i+1])\n        for j in range(lis[i],lis[i+1]):\n            qc.ch(lis[i+1],j)\n        qc.x(lis[i+1])\n        m = m + 2 ** (lis[i])\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A27EDFC756146", "submission_order": 2, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.ry(-1.91,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A27EDFC756146", "submission_order": 3, "result": "AC", "execution_time": "857 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    lis = []\n    k = 3\n    tmp = 0\n    while(k>0):\n        if k%2:\n            lis = lis + [tmp]\n        tmp += 1\n        k = k //2\n    m = 2 ** (lis[0])\n    \n    for i in range(1,len(lis)):\n        qc.x(lis[i])\n    if lis[0] > 0:\n        for i in range(lis[0]):\n            qc.h(i)\n    qc.ry(-2*math.acos(math.sqrt(m / 3)), lis[1])\n    qc.x(lis[1])\n    for i in range(lis[0],lis[1]):\n        qc.ch(lis[1], i)\n    qc.x(lis[1])        \n    for i in range(1,len(lis) - 1):\n        qc.x(lis[i]) \n        qc.cry(-2 * math.acos(math.sqrt(2 ** lis[i] / (3 - m))), lis[i], lis[i+1])\n        qc.x(lis[i])\n        qc.x(lis[i+1])\n        for j in range(lis[i],lis[i+1]):\n            qc.ch(lis[i+1],j)\n        qc.x(lis[i+1])\n        m = m + 2 ** (lis[i])\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A294325BE7E2D", "submission_order": 1, "result": "RE", "execution_time": "826 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A294325BE7E2D", "submission_order": 2, "result": "AC", "execution_time": "940 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2CBCD0591BA6", "submission_order": 1, "result": "RE", "execution_time": "1737 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(atan(1/2)*2)\n    qc.ch(0, 1, ctrl_state=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2CBCD0591BA6", "submission_order": 2, "result": "WA", "execution_time": "1841 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(atan(1/2)*2, 0)\n    qc.ch(0, 1, ctrl_state=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2CBCD0591BA6", "submission_order": 3, "result": "AC", "execution_time": "1860 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(atan(sqrt(1/2))*2, 0)\n    qc.ch(0, 1, ctrl_state=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 1, "result": "WA", "execution_time": "828 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi * 2/ 3, 0)\n    qc.h(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 2, "result": "RE", "execution_time": "743 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi / 3)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 3, "result": "RE", "execution_time": "1082 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.acos(1 / 3))\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 4, "result": "RE", "execution_time": "737 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 5, "result": "RE", "execution_time": "831 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.rx(math.pi * 1 / 3)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 6, "result": "RE", "execution_time": "967 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.acos(2 / math.sqrt(3)))\n    # qc.rx(math.pi * 1 / 3)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 7, "result": "RE", "execution_time": "759 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # x qc.rx(math.acos(2 / math.sqrt(3)))\n    qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 8, "result": "RE", "execution_time": "761 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # x qc.rx(math.acos(2 / math.sqrt(3)))\n    # x qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.ry(math.acos(math.sqrt(1/3)))\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 9, "result": "RE", "execution_time": "767 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # x qc.rx(math.acos(2 / math.sqrt(3)))\n    # x qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.rx(math.pi * 2 * sqrt(2/3))\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 10, "result": "RE", "execution_time": "1377 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # x qc.rx(math.acos(2 / math.sqrt(3)))\n    # x qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.rx(2 * math.acos(sqrt(2/3)), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 11, "result": "WA", "execution_time": "851 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # x qc.rx(math.acos(2 / math.sqrt(3)))\n    # x qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.rx(2 * math.acos(math.sqrt(2/3)), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 12, "result": "RE", "execution_time": "747 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # x qc.rx(math.acos(2 / math.sqrt(3)))\n    # x qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.rx(2 * math.acos(math.sqrt(2/3)), 0) # 00->1/3, 01->1/3\n    qc.cx(0)\n    qc.ch(0, 1)\n    qc.cx(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 13, "result": "WA", "execution_time": "872 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # x qc.rx(math.acos(2 / math.sqrt(3)))\n    # x qc.rx(math.acos(1 / math.sqrt(3)))\n    qc.rx(2 * math.acos(math.sqrt(2/3)), 0) # 00->1/3, 01->1/3\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 14, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.rx(2 * math.acos(math.sqrt(2/3)), 0) # 00->1/3, 01->1/3\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 15, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.rx(2 * math.acos(math.sqrt(2/3)), 0) # 00->2/3, 01->1/3\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2F3E1693A100", "submission_order": 16, "result": "AC", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.rx(2 * math.acos(math.sqrt(2/3)), 0) # 00->2/3, 01->1/3\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    qc.s(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FD74C0775A8", "submission_order": 1, "result": "AC", "execution_time": "817 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.ry(2 * math.atan(math.sqrt(2)), 0)\n  qc.ch(0, 1)\n  qc.x(0)\n  return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 1, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.r(2*math.pi/3,0,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 2, "result": "RE", "execution_time": "834 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(2*math.pi/3,0)\n    qc.ch(0,1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 3, "result": "RE", "execution_time": "835 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(2*math.pi/3,0)\n    qc.ch(0,1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 4, "result": "RE", "execution_time": "750 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(math.pi/3,0)\n    qc.ch(0,1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 5, "result": "RE", "execution_time": "1637 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.r(2*math.acos(1/math.sqrt(3)),0,0)\n    qc.ch(0,1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 6, "result": "RE", "execution_time": "724 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.r(1,0,0)\n    qc.ch(0,1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 7, "result": "RE", "execution_time": "779 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.r(2.0,0.0,0)\n    qc.ch(0,1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 8, "result": "RE", "execution_time": "719 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.r(math.pi/3,0,0)\n    qc.ch(0,1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 9, "result": "RE", "execution_time": "741 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.r(2*math.pi/3,0,0)\n    qc.ch(0,1)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 10, "result": "WA", "execution_time": "838 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.r(2*math.acos(1/math.sqrt(3)),0,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 11, "result": "WA", "execution_time": "831 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.r(math.acos(1/math.sqrt(3)),0,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 12, "result": "WA", "execution_time": "1145 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(2*math.acos(1/math.sqrt(3)),0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 13, "result": "WA", "execution_time": "821 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(math.acos(1/math.sqrt(3)),0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 14, "result": "WA", "execution_time": "836 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.ry(math.acos(1/math.sqrt(3)),0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A2FF19E1EEA23", "submission_order": 15, "result": "AC", "execution_time": "837 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.ry(2*math.acos(1/math.sqrt(3)),0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A31058F6AEF1A", "submission_order": 1, "result": "WA", "execution_time": "871 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2, 2)\n    # Write your code here:\n     # Hadamardゲートを2つの量子ビットに適用\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0, 1)\n    qc.measure(1, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A31058F6AEF1A", "submission_order": 2, "result": "WA", "execution_time": "1064 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2, 2)\n    # Write your code here:\n     # Hadamardゲートを2つの量子ビットに適用\n    qc.h(0)\n    qc.h(1)\n    qc.ch(0, 1)\n    qc.measure(0, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A31FCF5F276F5", "submission_order": 1, "result": "AC", "execution_time": "832 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(2.0/3.0))*2.0, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A329CB0100453", "submission_order": 1, "result": "AC", "execution_time": "1835 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ry(math.asin(1 / 3), 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A5", "user": "A32DEB4A3B48F", "submission_order": 1, "result": "AC", "execution_time": "1165 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3427313186FE", "submission_order": 1, "result": "AC", "execution_time": "889 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos, pi\n \ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\ttheta = 2 * acos(1 / sqrt(3))\n\tqc.x(0)\n\tqc.cry(theta, 0, 1)\n\tqc.ch(1, 0)\n\tqc.cz(0, 1)\n\tqc.x(0)\n\tqc.x(1)\n\treturn qc\n'''"}
{"problem": "QPC001_A5", "user": "A35AF7D9E8661", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.asin(math.sqrt(1/3))\n    qc.ry(theta, 0)\n    qc.ry(math.pi/2, 1)\n    qc.cry(math.pi/2,0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3A6548084D9B", "submission_order": 1, "result": "AC", "execution_time": "1605 ms", "memory": "162 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(2))\n    qc.ry(theta=theta, qubit=0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3C0A6E066257", "submission_order": 1, "result": "RE", "execution_time": "786 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(4*math.atan(math.sqrt(3)/(3+math.sqrt(6))))\n    qc.cry(-math.pi/2, 1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3C0A6E066257", "submission_order": 2, "result": "AC", "execution_time": "856 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(4*math.atan(math.sqrt(3)/(3+math.sqrt(6))), 1)\n    qc.cry(-math.pi/2, 1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3C529D984B52", "submission_order": 1, "result": "WA", "execution_time": "1602 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Specific rotation angles to create equal superposition of 3 states\n    theta1 = 2 * np.arccos(np.sqrt(2/3))  # ≈ 1.231 radians\n    theta2 = np.pi/2  # 90 degrees\n    \n    qc.ry(theta1, 1)        # Rotate qubit 1 \n    qc.cry(theta2, 1, 0)    # Controlled rotation on qubit 0\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3C529D984B52", "submission_order": 2, "result": "AC", "execution_time": "1594 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 2 * math.atan(math.sqrt(2))\n    qc.ry(t,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 1, "result": "RE", "execution_time": "843 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.u3(math.acos(2/math.sqrt(3))*2,0,0,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 2, "result": "RE", "execution_time": "774 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.u3(math.acos(math.sqrt(2/3))*2,0,0,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 3, "result": "RE", "execution_time": "775 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.u3(0,0,0,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 4, "result": "RE", "execution_time": "2000 ms", "memory": "81 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u3(0,0,0,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 5, "result": "RE", "execution_time": "2000 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.u3(PI()/2,0,0,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 6, "result": "RE", "execution_time": "769 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.u3(2*math.acos(math.sqrt(2/3)),0,0,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 7, "result": "RE", "execution_time": "930 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.u(2*math.acos(math.sqrt(2/)),0,0,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 8, "result": "RE", "execution_time": "1156 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    uni=np.array()\n    qc.rx(2*math.acos(math.sqrt(1/3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 9, "result": "WA", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(2*math.acos(math.sqrt(1/3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 10, "result": "WA", "execution_time": "899 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(2*math.acos(math.sqrt(2/3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 11, "result": "WA", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(math.acos(math.sqrt(1/3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 12, "result": "WA", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(math.acos(math.sqrt(2/3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 13, "result": "WA", "execution_time": "862 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.rx(2*(math.acos(math.sqrt(2/3))),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 14, "result": "WA", "execution_time": "813 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta=2*(math.acos(math.sqrt(2/3)))\n    qc.rx(theta,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 15, "result": "WA", "execution_time": "1350 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta=math.acos(math.sqrt(1/3))\n    qc.ry(theta,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D30FB906A0F", "submission_order": 16, "result": "AC", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta=2*math.acos(math.sqrt(1/3))\n    qc.ry(theta,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D831DADA0D7", "submission_order": 1, "result": "AC", "execution_time": "1761 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2*math.acos(1/math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D9B0AEFEA45", "submission_order": 1, "result": "RE", "execution_time": "1287 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    wanted_cos = (2/3)**0.5\n    theta = math.acos(wanted_cos) * 2\n\n    qc.x(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D9B0AEFEA45", "submission_order": 2, "result": "WA", "execution_time": "1381 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    wanted_cos = (2/3)**0.5\n    theta = math.acos(wanted_cos) * 2\n\n    qc.x(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3D9B0AEFEA45", "submission_order": 3, "result": "AC", "execution_time": "1306 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    wanted_cos = (2/3)**0.5\n    theta = - math.acos(wanted_cos) * 2\n\n    qc.x(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3F24C4262C5F", "submission_order": 1, "result": "RE", "execution_time": "2003 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    theta = 4 * math.atan(math.sqrt(6)/(3+math.sqrt((3))))\n    qc.ry(thata, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3F24C4262C5F", "submission_order": 2, "result": "RE", "execution_time": "1863 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    theta = 4 * math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(thata, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3F24C4262C5F", "submission_order": 3, "result": "AC", "execution_time": "2028 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    theta = 4 * math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3F911BB4FE8B", "submission_order": 1, "result": "RE", "execution_time": "1379 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state = (np.sqrt(3) ** -1) * np.array([1,1,1,0])    \n    qc.initialize(state)\n    qc = qc.decompose().decompose().decompose().decompose().decompose().decompose()\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3F911BB4FE8B", "submission_order": 2, "result": "AC", "execution_time": "1532 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    state = (np.sqrt(3) ** -1) * np.array([1,1,1,0])    \n    qc.initialize(state)\n    qc = qc.decompose().decompose().decompose().decompose().decompose().decompose()\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3FDBC71355FF", "submission_order": 1, "result": "RE", "execution_time": "1344 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2.0*math.arccos(1/math.sqrt(3))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A3FDBC71355FF", "submission_order": 2, "result": "AC", "execution_time": "1315 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2.0*math.acos(1/math.sqrt(3))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A404B40268C57", "submission_order": 1, "result": "RE", "execution_time": "1228 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    U = np.array([[1/math.sqrt(3),1/math.sqrt(3),1/math.sqrt(3),0], [0,1,0,0], [0,0,1,0], [0,0,0,1]])\n    qc.unitary(U, qubits = qc.qubits, label = \"U\")\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A404B40268C57", "submission_order": 2, "result": "AC", "execution_time": "1105 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))) \n    qc.ry(theta, 0) # to get 1/sqrt(3)|00> + sqrt(2)/sqrt(3)|10>\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A41E3E9BFAEE2", "submission_order": 1, "result": "WA", "execution_time": "811 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # アダマールゲートを各量子ビットに適用\n    qc.h(0)\n    qc.h(1)\n    \n    # CNOTゲートを使用してエンタングルメントを作り出す\n    qc.cx(0, 1)\n    \n    # 各量子ビットにアダマールゲートを再度適用\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 1, "result": "WA", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cry(2 * math.acos(1 / math.sqrt(3)), 0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 2, "result": "WA", "execution_time": "1230 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(2/3))\n    qc.cry(angle, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 3, "result": "RE", "execution_time": "1018 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(2/3))\n    qc.cry(angle, 0, 2)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 4, "result": "RE", "execution_time": "781 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(2/3))\n    qc.cry(angle, 0, 2)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 5, "result": "WA", "execution_time": "1295 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    # angle = 2 * math.asin(math.sqrt(2/3))\n    # qc.cry(angle, 0, 2)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 6, "result": "WA", "execution_time": "1158 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(2/3))\n    # qc.cry(angle, 0, 2)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 7, "result": "RE", "execution_time": "748 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(2/3))\n    qc.cry(angle, 0, 2,label=None, ctrl_state=None)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 8, "result": "WA", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(2/3))\n    qc.cry(0.2, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 9, "result": "WA", "execution_time": "1067 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(2/3))\n    degree_angle = angle * 180 / math.pi\n    qc.cry(degree_angle, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 10, "result": "WA", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(2/3))\n    qc.cry(angle, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 11, "result": "WA", "execution_time": "870 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    angle = 2 * math.asin(math.sqrt(1/3))\n    qc.cry(angle, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 12, "result": "WA", "execution_time": "1196 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cry(2 * math.asin(1 / math.sqrt(3)), 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 13, "result": "WA", "execution_time": "852 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cry(2 * math.asin(1 / math.sqrt(3)), 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 14, "result": "WA", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cry(2 * math.acos(1 / math.sqrt(3)), 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 15, "result": "WA", "execution_time": "946 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.ry(-theta/2, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 16, "result": "WA", "execution_time": "933 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.ry(-theta/2, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 17, "result": "WA", "execution_time": "1521 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    # qc.ry(-theta/2, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A422D39AC9A75", "submission_order": 18, "result": "WA", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.ry(-theta/2, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A44ECF1050F6F", "submission_order": 1, "result": "WA", "execution_time": "1041 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2.0*math.acos(math.sqrt(2.0)/math.sqrt(3.0)), 0)\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A44ECF1050F6F", "submission_order": 2, "result": "WA", "execution_time": "806 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(2.0*math.acos(math.sqrt(2.0)/math.sqrt(3.0)), 0)\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A44ECF1050F6F", "submission_order": 3, "result": "WA", "execution_time": "1011 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(2.0)/math.sqrt(3.0)), 0)\n    qc.ch(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A44ECF1050F6F", "submission_order": 4, "result": "WA", "execution_time": "818 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2.0*math.acos(math.sqrt(2.0)/math.sqrt(3.0)), 0)\n    qc.x(range(2))\n    qc.ch(0, 1)\n    qc.x(range(2))\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A44ECF1050F6F", "submission_order": 5, "result": "AC", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2.0*math.acos(math.sqrt(2.0)/math.sqrt(3.0)), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4502C14FC5DB", "submission_order": 1, "result": "RE", "execution_time": "817 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2.0*math.acos(1.0/sqrt(3.0))\n    # Write your code here:\n    qc.u(theta,0,0,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4502C14FC5DB", "submission_order": 2, "result": "WA", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2.0*math.acos(1.0/math.sqrt(3.0))\n    # Write your code here:\n    qc.u(theta,0,0,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4502C14FC5DB", "submission_order": 3, "result": "AC", "execution_time": "946 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2.0*math.acos(1.0/math.sqrt(3.0))\n    # Write your code here:\n    qc.u(theta,0,0,0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A450DBB895889", "submission_order": 1, "result": "WA", "execution_time": "1478 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(t, 0)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A450DBB895889", "submission_order": 2, "result": "AC", "execution_time": "1507 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(t, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A46D6A838D252", "submission_order": 1, "result": "RE", "execution_time": "747 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2*math.acos(1/math.sqrt(3))\n    qc.ry(angle, 0)\n    qc.cx(0,1)\n    qc.ch(1,0)\n    qc.cp(math.pi, 0,1)\n    qc.cx(0,1)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A46D6A838D252", "submission_order": 2, "result": "AC", "execution_time": "864 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2*math.acos(1/math.sqrt(3))\n    qc.ry(angle, 0)\n    qc.cx(0,1)\n    qc.ch(1,0)\n    qc.cp(math.pi, 0,1)\n    qc.cx(0,1)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4755BF4D84AA", "submission_order": 1, "result": "RE", "execution_time": "785 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    val = 1 / math.sqrt(3)\n    gate = Operator([\n        [val, 0, 0, 0],\n        [val, 0, 0, 0],\n        [val, 0, 0, 0],\n        [0, 0, 0, 0]\n    ])\n\n    qc.g(gate)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4755BF4D84AA", "submission_order": 2, "result": "RE", "execution_time": "763 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    val = 1 / math.sqrt(3)\n    gate = [\n        [val, 0, 0, 0],\n        [val, 0, 0, 0],\n        [val, 0, 0, 0],\n        [0, 0, 0, 0]\n    ]\n\n    qc.g(gate)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4755BF4D84AA", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Operator\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    val = 1 / math.sqrt(3)\n    gate = Operator([\n        [val, 0, 0, 0],\n        [val, 0, 0, 0],\n        [val, 0, 0, 0],\n        [0, 0, 0, 0]\n    ])\n\n    qc.g(gate)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4755BF4D84AA", "submission_order": 4, "result": "RE", "execution_time": "790 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    val = 1.0 / math.sqrt(3)\n    gate = np.array([\n        [val, 0, 0, 0],\n        [val, 0, 0, 0],\n        [val, 0, 0, 0],\n        [0, 0, 0, 0]\n    ])\n\n    qc.g(gate)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4755BF4D84AA", "submission_order": 5, "result": "WA", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    val = 1.0 / math.sqrt(3)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4755BF4D84AA", "submission_order": 6, "result": "WA", "execution_time": "854 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    val = 1.0 / math.sqrt(3)\n    \n    qc.h(1)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A48487392821C", "submission_order": 1, "result": "RE", "execution_time": "1429 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ry(2 * sqrt(1/3), 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A48487392821C", "submission_order": 2, "result": "WA", "execution_time": "1410 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.h(0)\n    qc.ry(2.0944, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A48487392821C", "submission_order": 3, "result": "RE", "execution_time": "1460 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    desired_state = [1/sqrt(3), 1/sqrt(3), 1/sqrt(3), 0]\n    qc.initialize(desired_state, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A48487392821C", "submission_order": 4, "result": "WA", "execution_time": "1466 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.h(0)\n    qc.cx(0,1)\n    qc.ry(2 * math.sqrt(1/3), 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A49CCF8034620", "submission_order": 1, "result": "RE", "execution_time": "1501 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(0) # Apply on the 1st qubit to create the superposition\n\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 1)\n\n    qc.cx(0, 1)\n\n    qc.ry(2 * np.arcsin(1 / np.sqrt(2)), 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A49CCF8034620", "submission_order": 2, "result": "WA", "execution_time": "1619 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Apply Ry gate to the first qubit to create the right superposition\n    theta = 2 * np.arcsin(np.sqrt(1/3))\n    qc.ry(theta, 0)  # Rotates the first qubit to prepare part of the superposition\n    \n    # Step 2: Apply a CNOT gate controlled on the first qubit to the second qubit\n    qc.cx(0, 1)  # Entangles the first and second qubits\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A49CF3D17A067", "submission_order": 1, "result": "AC", "execution_time": "921 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4A045661199B", "submission_order": 1, "result": "WA", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a = 70.52881816\n    b = 29.99999738\n\n    qc.h(0)\n    qc.cry(pi/180*a, 0, 1)\n    qc.cx(1,0)\n    qc.cry(pi/180*b, 1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A4A045661199B", "submission_order": 2, "result": "WA", "execution_time": "1008 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a = 11.0\n    b = 0.3\n\n    qc.h(0)\n    qc.cry(a, 0, 1)\n    qc.cx(1,0)\n    qc.cry(b, 1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 1, "result": "RE", "execution_time": "963 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(math.sqrt(2))\n    qc.rx(theta)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 2, "result": "RE", "execution_time": "799 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(math.sqrt(2),0)\n    qc.rx(theta)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 3, "result": "RE", "execution_time": "745 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(math.sqrt(2),0)\n    qc.rx(theta)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 4, "result": "WA", "execution_time": "957 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(math.sqrt(2))\n    qc.rx(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 5, "result": "WA", "execution_time": "909 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(math.sqrt(2))\n    qc.rx(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 6, "result": "WA", "execution_time": "818 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(math.sqrt(2))\n    qc.rx(theta,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 7, "result": "WA", "execution_time": "795 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(math.sqrt(2))\n    qc.rx(theta,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 8, "result": "WA", "execution_time": "1038 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(2*math.sqrt(2)/(1-math.sqrt(2)))\n    qc.ry(theta,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 9, "result": "WA", "execution_time": "980 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(-(2*math.sqrt(2)+4))\n    qc.ry(theta,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 10, "result": "WA", "execution_time": "915 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(-(2*math.sqrt(2)+4))\n    qc.rx(theta,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 11, "result": "WA", "execution_time": "938 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta =  math.atan(-(2*math.sqrt(2)))\n    qc.rx(theta,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5187FA9ADF9D", "submission_order": 12, "result": "AC", "execution_time": "985 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A52093297E911", "submission_order": 1, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    rad = 2 / 3**0.5\n    qc.rx(rad, 1)\n    qc.cx(0, 1)\n    qc.rx(rad, 1)\n    qc.rz(rad, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A52093297E911", "submission_order": 2, "result": "WA", "execution_time": "1081 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    rad = 2 / sqrt(3)\n    qc.rx(rad, 1)\n    qc.cx(0, 1)\n    qc.rx(rad, 1)\n    qc.rz(rad, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A52093297E911", "submission_order": 3, "result": "WA", "execution_time": "932 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import asin, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.ry(2*asin(sqrt(1/sqrt(3))), 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A522C2F99DAEA", "submission_order": 1, "result": "WA", "execution_time": "1683 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt, acos\n    coef = sqrt(1/3)\n    theta = acos(coef) * 2\n\n    qc.u(theta, 0, 0, 0)\n    qc.ch(0, 1)\n\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A522C2F99DAEA", "submission_order": 2, "result": "WA", "execution_time": "1612 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt, acos\n    coef = sqrt(1/3)\n    theta = acos(coef) * 2\n\n    qc.u(theta, 0, 0, 0)\n    qc.ch(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A522C2F99DAEA", "submission_order": 3, "result": "AC", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from math import sqrt, acos\n    coef = sqrt(1/3)\n    theta = acos(coef) * 2\n\n    qc.u(theta, 0, 0, 0)\n    qc.ch(0, 1)\n\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A52398A648F1C", "submission_order": 1, "result": "AC", "execution_time": "1072 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(2.*math.acos(1./math.sqrt(3.)),0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5573543CFEFB", "submission_order": 1, "result": "RE", "execution_time": "1491 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5573543CFEFB", "submission_order": 2, "result": "AC", "execution_time": "1528 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A57068293C8FF", "submission_order": 1, "result": "RE", "execution_time": "1981 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * arccos(1 / (3**0.5))\n    qc.ry(theta,0),\n    qc.ch(1), \n    qc.x(0),\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A57068293C8FF", "submission_order": 2, "result": "RE", "execution_time": "2019 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta,0),\n    qc.ch(1), \n    qc.x(0),\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A57068293C8FF", "submission_order": 3, "result": "RE", "execution_time": "1847 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1/math.sqrt(3))\n    qc.ry(theta,0),\n    qc.ch(1), \n    qc.x(0),\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A57068293C8FF", "submission_order": 4, "result": "AC", "execution_time": "1988 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1/math.sqrt(3))\n    qc.ry(theta,0),\n    qc.ch(0,1), \n    qc.x(0),\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A58ED57EBC734", "submission_order": 1, "result": "RE", "execution_time": "1823 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.acos(1 / sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.c(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A58ED57EBC734", "submission_order": 2, "result": "RE", "execution_time": "1734 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.acos(1 / math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.c(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A58ED57EBC734", "submission_order": 3, "result": "WA", "execution_time": "1883 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.acos(1 / math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A58ED57EBC734", "submission_order": 4, "result": "AC", "execution_time": "1872 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(2))\n    qc.ry(th, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AA1712A2D49", "submission_order": 1, "result": "WA", "execution_time": "903 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(1.2310,0)\n    qc.ry(math.pi/4,1)\n    qc.x(0)\n    qc.cnot(0,1)\n    qc.x(0)\n    qc.ry(-1*math.pi/4,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AA1712A2D49", "submission_order": 2, "result": "WA", "execution_time": "967 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(1.2310,0)\n    qc.ry(math.pi/4,1)\n    qc.x(0)\n    qc.cnot(0,1)\n    qc.x(0)\n    qc.ry(-1*math.pi/4,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AA1712A2D49", "submission_order": 3, "result": "WA", "execution_time": "853 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(1.2310,0)\n    qc.ry(math.pi/4,1)\n    qc.x(0)\n    qc.cnot(0,1)\n    qc.x(0)\n    qc.ry(-1*math.pi/4,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 1, "result": "RE", "execution_time": "1117 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 2, "result": "WA", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.append(CRYGate, [0, 1])\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 5, "result": "RE", "execution_time": "750 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n\n    qc.append(CRYGate, [0, 1])\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 6, "result": "RE", "execution_time": "2000 ms", "memory": "82 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n\n    qc.append(CRYGate(math.pi/2), [0, 1])\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 7, "result": "WA", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CRYGate\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n\n    qc.append(CRYGate(math.pi/2), [0, 1])\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 8, "result": "WA", "execution_time": "838 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CRYGate\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.x(0)\n    qc.append(CRYGate(math.pi/2), [0, 1])\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 9, "result": "WA", "execution_time": "879 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/3,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5AB310B4B775", "submission_order": 10, "result": "AC", "execution_time": "1676 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1/3),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5BF2909CE4B8", "submission_order": 1, "result": "WA", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    import math\n    qc.r(math.acos(-1/3)/2,math.pi/2,0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5BF2909CE4B8", "submission_order": 2, "result": "WA", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    import math\n    qc.ry((math.acos(-1/3))/2,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5E2237E97145", "submission_order": 1, "result": "RE", "execution_time": "1996 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * math.acos(sqrt(2/3))\n    qc.ry(theta, 0)\n\n    qc.cx(0, 1)\n    qc.x(1)\n\n    theta2 = math.pi / 2\n    qc.cry(theta2, 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5E2237E97145", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble, execute\nfrom math import sqrt, acos\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * acos(sqrt(2/3))\n    qc.ry(theta, 0)\n\n    qc.cx(0, 1)\n    qc.x(1)\n\n    theta2 = math.pi / 2\n    qc.cry(theta2, 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5E2237E97145", "submission_order": 3, "result": "RE", "execution_time": "1802 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * acos(sqrt(2/3))\n    qc.ry(theta, 0)\n\n    qc.cx(0, 1)\n    qc.x(1)\n\n    theta2 = math.pi / 2\n    qc.cry(theta2, 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5E2237E97145", "submission_order": 4, "result": "WA", "execution_time": "1939 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * math.acos(math.sqrt(2/3))\n    qc.ry(theta, 0)\n\n    qc.cx(0, 1)\n    qc.x(1)\n\n    theta2 = math.pi / 2\n    qc.cry(theta2, 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5E2237E97145", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * math.acos(math.sqrt(2/3))\n    qc.ry(theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5E2237E97145", "submission_order": 6, "result": "AC", "execution_time": "2024 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * math.acos(math.sqrt(2/3))\n    qc.ry(theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5EAB45B884AD", "submission_order": 1, "result": "RE", "execution_time": "1441 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    \n    theta = 2 * np.arccos(np.sqrt(1 / 3))\n    qc.cu(theta, 0, 0, 0, 0, 1)\n    qc.cx(1, 0)\n    qc.ch(1,2)\n    qc.cx(2,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5EAB45B884AD", "submission_order": 2, "result": "RE", "execution_time": "1515 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    \n    theta = 2 * arccos(sqrt(1 / 3))\n    qc.cu(theta, 0, 0, 0, 0, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 2)\n    qc.cx(2, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5EAB45B884AD", "submission_order": 3, "result": "RE", "execution_time": "1476 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    \n    theta = 2 * arccos(sqrt(1 / 3))\n    qc.cu(theta, 0, 0, 0, 0, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(range(2))\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A5EAB45B884AD", "submission_order": 4, "result": "AC", "execution_time": "1492 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    \n    theta = 2 * np.arccos(np.sqrt(1 / 3))\n    qc.cu(theta, 0, 0, 0, 0, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(range(2))\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A60B9C949F628", "submission_order": 1, "result": "WA", "execution_time": "1385 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.atan((2-math.sqrt(2))/(2+math.sqrt(2)))\n    qc.h(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A60B9C949F628", "submission_order": 2, "result": "AC", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan((2-math.sqrt(2))/(2+math.sqrt(2)))\n    qc.h(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A61FB4D52CC6A", "submission_order": 1, "result": "RE", "execution_time": "794 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(pi/3, 0)\n    qc.h(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A61FB4D52CC6A", "submission_order": 2, "result": "WA", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(pi/3, 0)\n    qc.h(1)\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A61FB4D52CC6A", "submission_order": 3, "result": "WA", "execution_time": "860 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(pi/3, 0)\n    qc.h(1)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A61FB4D52CC6A", "submission_order": 4, "result": "WA", "execution_time": "1963 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(pi/3, 0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A61FB4D52CC6A", "submission_order": 5, "result": "WA", "execution_time": "860 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CU1Gate, SwapGate\nfrom math import pi\n\n#def solve(n: int, L: int) -> QuantumCircuit:\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n    qc.ry(pi / 2.4, 0)\n\n    qc.ch(0, 1)\n    qc.x(0)\n\n    #qc.h(2)\n    #qc.cp(pi/2, 0, 2)\n    #qc.cp(pi/2, 1, 2)\n\n    #qc.h(1)\n    #qc.cp(pi/2, 0, 1)\n\n    #qc.h(0)\n\n    #qc.append(SwapGate(), [0, 2])\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A61FB4D52CC6A", "submission_order": 6, "result": "WA", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CU1Gate, SwapGate\nfrom math import pi\n\n#def solve(n: int, L: int) -> QuantumCircuit:\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n    qc.ry(pi / 2.5555, 0)\n\n    qc.ch(0, 1)\n    qc.x(0)\n\n    #qc.h(2)\n    #qc.cp(pi/2, 0, 2)\n    #qc.cp(pi/2, 1, 2)\n\n    #qc.h(1)\n    #qc.cp(pi/2, 0, 1)\n\n    #qc.h(0)\n\n    #qc.append(SwapGate(), [0, 2])\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A61FB4D52CC6A", "submission_order": 7, "result": "WA", "execution_time": "832 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CU1Gate, SwapGate\nfrom math import pi\n\n#def solve(n: int, L: int) -> QuantumCircuit:\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n    qc.ry(pi / 2.555, 0)\n\n    qc.ch(0, 1)\n    qc.x(0)\n\n    #qc.h(2)\n    #qc.cp(pi/2, 0, 2)\n    #qc.cp(pi/2, 1, 2)\n\n    #qc.h(1)\n    #qc.cp(pi/2, 0, 1)\n\n    #qc.h(0)\n\n    #qc.append(SwapGate(), [0, 2])\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A62B08AE40154", "submission_order": 1, "result": "RE", "execution_time": "968 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(np.pi * 60 / 180, 0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A62B08AE40154", "submission_order": 2, "result": "WA", "execution_time": "1146 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi * 60 / 180, 0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A62B08AE40154", "submission_order": 3, "result": "WA", "execution_time": "1832 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.asin(1 / 3 ** 0.5), 0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A62B08AE40154", "submission_order": 4, "result": "WA", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.acos(1 / 3 ** 0.5), 0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A62B08AE40154", "submission_order": 5, "result": "RE", "execution_time": "767 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.acos(2 / 3 ** 0.5) / 2, 0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A62B08AE40154", "submission_order": 6, "result": "WA", "execution_time": "1405 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.acos((2 / 3) ** 0.5) / 2, 0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A62B08AE40154", "submission_order": 7, "result": "AC", "execution_time": "1066 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.asin(1 / (3 ** 0.5)) * 2, 0)\n    qc.h(1)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A632A9CFFCB33", "submission_order": 1, "result": "WA", "execution_time": "1386 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.asin(2/3), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A632A9CFFCB33", "submission_order": 2, "result": "AC", "execution_time": "1347 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.asin(math.sqrt(2/3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6482FCAF4A43", "submission_order": 1, "result": "RE", "execution_time": "1746 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * acos(1 / sqrt(3))\n\n    qc.ry(theta, 0)\n    qc.h(0, 1)\n    qc.cx(1, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6482FCAF4A43", "submission_order": 2, "result": "AC", "execution_time": "1903 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * acos(1 / sqrt(3))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6728CC3B09A6", "submission_order": 1, "result": "WA", "execution_time": "1572 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6728CC3B09A6", "submission_order": 2, "result": "WA", "execution_time": "1470 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(2*angle, 0)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6728CC3B09A6", "submission_order": 3, "result": "WA", "execution_time": "1547 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(angle, 1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6728CC3B09A6", "submission_order": 4, "result": "AC", "execution_time": "1463 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    angle=np.arccos(1/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A69A0B674290B", "submission_order": 1, "result": "RE", "execution_time": "1263 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # qubit0 を sqrt(2/3)|0> + sqrt(1/3)|1> にするための角度 theta\n    theta = 2 * np.arcsin(np.sqrt(1/3))\n    qc.ry(theta, 0)\n    \n    # qubit0 が |0> のときに qubit1 に Hadamard を適用する\n    # → まず qubit0 に X を適用して反転させ、CH を適用してから再度 X を適用\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A69A0B674290B", "submission_order": 2, "result": "AC", "execution_time": "1364 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # qubit0 を sqrt(2/3)|0> + sqrt(1/3)|1> にするための角度 theta\n    theta = 2 * np.arcsin(np.sqrt(1/3))\n    qc.ry(theta, 0)\n    \n    # qubit0 が |0> のときに qubit1 に Hadamard を適用する\n    # → まず qubit0 に X を適用して反転させ、CH を適用してから再度 X を適用\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A69F322EB8BE0", "submission_order": 1, "result": "RE", "execution_time": "817 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.rx(math.asin(1/math.sqrt(3)) * math.pi)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A69F322EB8BE0", "submission_order": 2, "result": "WA", "execution_time": "793 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.rx(math.asin(1/math.sqrt(3)) * math.pi, 0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A69F322EB8BE0", "submission_order": 3, "result": "WA", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.rx(math.asin(1/math.sqrt(3)) * math.pi, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6C262456BCDA", "submission_order": 1, "result": "RE", "execution_time": "953 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1/math.sqrt(3))\n    qc.ry(theta, 0)\n\n    gamma = math.pi\n    qc.cry(gamma/2, 0, 1)\n    qc.cx(1, 0) \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6C262456BCDA", "submission_order": 2, "result": "RE", "execution_time": "790 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1/math.sqrt(3))\n    qc.ry(theta, 0)\n\n    gamma = math.pi/2\n    qc.cry(gamma/2, 0, 1)\n    qc.cx(1, 0) \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6C262456BCDA", "submission_order": 3, "result": "AC", "execution_time": "992 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1/math.sqrt(3))\n    qc.ry(theta, 0)\n\n    gamma = math.pi\n    qc.cry(gamma/2, 0, 1)\n    qc.cx(1, 0) \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6CD4CB3813B0", "submission_order": 1, "result": "AC", "execution_time": "1850 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import asin\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = asin((2/3)**(1/2))\n    qc.ry(2*theta,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6D18EF331E00", "submission_order": 1, "result": "AC", "execution_time": "1979 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6D4E0295C92D", "submission_order": 1, "result": "RE", "execution_time": "804 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h([0,1])\n    qc.cx(1,0)\n    qc.cx(0,)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6D4E0295C92D", "submission_order": 2, "result": "WA", "execution_time": "1665 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h([0,1])\n    qc.cx(1,0)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6D4E0295C92D", "submission_order": 3, "result": "WA", "execution_time": "855 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h([0,1])\n    qc.x(1)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6D4E0295C92D", "submission_order": 4, "result": "WA", "execution_time": "1163 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h([0,1])\n    qc.cx(1,0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6D4E0295C92D", "submission_order": 5, "result": "WA", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(1)\n    qc.cx(1,0)\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6FA35269DA1A", "submission_order": 1, "result": "RE", "execution_time": "1648 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.arctan(math.sqrt(2))\n    qc.ry(theta * 2)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6FA35269DA1A", "submission_order": 2, "result": "RE", "execution_time": "1611 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.arctan(math.sqrt(2))\n    qc.ry(theta * 2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6FA35269DA1A", "submission_order": 3, "result": "RE", "execution_time": "1704 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.atan(math.sqrt(2))\n    qc.ry(theta * 2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6FA35269DA1A", "submission_order": 4, "result": "RE", "execution_time": "1658 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.atan(math.sqrt(2))\n    qc.ry(theta * 2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A6FA35269DA1A", "submission_order": 5, "result": "AC", "execution_time": "1760 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.atan(math.sqrt(2))\n    qc.ry(theta * 2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A702569C03050", "submission_order": 1, "result": "WA", "execution_time": "799 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0) \n    qc.h(1) \n    qc.x(1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A702569C03050", "submission_order": 2, "result": "RE", "execution_time": "800 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * np.arccos(1/np.sqrt(3))\n    qc.ry(angle, 0)\n     qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A702569C03050", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    theta = 2 * np.arccos(np.sqrt(2/3)) \n    qc.cry(theta, 1, 0) \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A70621051CFC8", "submission_order": 1, "result": "WA", "execution_time": "1740 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos((1/3) ** 1/2)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A70621051CFC8", "submission_order": 2, "result": "WA", "execution_time": "1654 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.atan(1/2 ** 1/2)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A70621051CFC8", "submission_order": 3, "result": "WA", "execution_time": "1713 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.atan(2 ** 0.5)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A70621051CFC8", "submission_order": 4, "result": "AC", "execution_time": "1713 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan(2 ** 0.5)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A758948856B9C", "submission_order": 1, "result": "WA", "execution_time": "1178 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(math.pi*253/416, math.pi, math.pi,1)\n    qc.ch(1,0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A758948856B9C", "submission_order": 2, "result": "WA", "execution_time": "820 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(math.pi*253/416, math.pi, math.pi,0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A758948856B9C", "submission_order": 3, "result": "AC", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.u(math.pi*253/416,math.pi, math.pi,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A75C25CE5C057", "submission_order": 1, "result": "AC", "execution_time": "1338 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A75E14414D7F1", "submission_order": 1, "result": "RE", "execution_time": "750 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(acos(1/sqrt(3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A75E14414D7F1", "submission_order": 2, "result": "RE", "execution_time": "751 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(acos(1/sqrt(3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A75E14414D7F1", "submission_order": 3, "result": "RE", "execution_time": "775 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(acos(1/sqrt(3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A75E14414D7F1", "submission_order": 4, "result": "WA", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1/math.sqrt(3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A75E14414D7F1", "submission_order": 5, "result": "AC", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A767F90211572", "submission_order": 1, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(1.91, 0, math.pi, qubit=0)\n    qc.cx(1, 0)\n    qc.csx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A767F90211572", "submission_order": 2, "result": "WA", "execution_time": "842 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(1.91, 0, math.pi, qubit=0)\n    qc.cx(1, 0)\n    qc.csx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A767F90211572", "submission_order": 3, "result": "WA", "execution_time": "890 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u(1.91062, 0, math.pi, qubit=0)\n    qc.cx(1, 0)\n    qc.csx(0, 1)\n    qc.cx(1, 0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A767F90211572", "submission_order": 4, "result": "AC", "execution_time": "828 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.u(1.91062, 0, math.pi, qubit=0)\n    qc.cx(1, 0)\n    qc.csx(0, 1)\n    qc.cx(1, 0)\n    qc.p(3 * math.pi / 4, 0)\n    qc.p(math.pi / 4, 1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A77C0599582EF", "submission_order": 1, "result": "RE", "execution_time": "1456 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * arctan(np.sqrt(2))\n    qc.ry(theta, 0)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A77C0599582EF", "submission_order": 2, "result": "WA", "execution_time": "1485 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * np.arctan(np.sqrt(2))\n    qc.ry(theta, 0)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A77C0599582EF", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 4 * np.arctan((np.sqrt(3)-1) /np.sqrt(2))\n    qc.ry(theta, 01\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A77C0599582EF", "submission_order": 4, "result": "AC", "execution_time": "1512 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 4 * np.arctan((np.sqrt(3)-1) /np.sqrt(2))\n    qc.ry(theta, 1)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7822E5A4F2E8", "submission_order": 1, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/(3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7952DA67B69F", "submission_order": 1, "result": "WA", "execution_time": "1424 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(108.2712, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7952DA67B69F", "submission_order": 2, "result": "WA", "execution_time": "1627 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(1.91, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7952DA67B69F", "submission_order": 3, "result": "AC", "execution_time": "1510 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(1.9106332345998, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7AF9DC877455", "submission_order": 1, "result": "AC", "execution_time": "1603 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(0.5 * (math.sqrt(6)-math.sqrt(2)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7B89549BCB53", "submission_order": 1, "result": "WA", "execution_time": "2000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry((2/3)**0.5, 0); qc.ch(0, 1); qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7B89549BCB53", "submission_order": 2, "result": "AC", "execution_time": "1288 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.9106332362490184, 0); qc.ch(0, 1); qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7BD67587B20E", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    theta2 = (np.pi/4)\n\n    qc.ry(theta=theta1, qubit=0)\n    qc.ry(theta=theta2, qubit=1)\n    qc.cx(control_qubit=0, target_qubit=1)\n    qc.ry(theta=-theta2, qubit=1)\n    qc.x(qubit=0)e:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7BD67587B20E", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    theta2 = (np.pi/4)\n\n    qc.ry(theta=theta1, qubit=0)\n    qc.ry(theta=theta2, qubit=1)\n    qc.cx(control_qubit=0, target_qubit=1)\n    qc.ry(theta=-theta2, qubit=1)\n    qc.x(qubit=0)e\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7BD67587B20E", "submission_order": 3, "result": "AC", "execution_time": "2117 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    theta2 = (np.pi/4)\n\n    qc.ry(theta=theta1, qubit=0)\n    qc.ry(theta=theta2, qubit=1)\n    qc.cx(control_qubit=0, target_qubit=1)\n    qc.ry(theta=-theta2, qubit=1)\n    qc.x(qubit=0)#\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7C405141A149", "submission_order": 1, "result": "WA", "execution_time": "972 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.atan(2) * 2, 0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.t(0)\n    qc.tdg(1)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.h(1)\n    qc.tdg(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.sdg(0)\n    qc.s(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7C405141A149", "submission_order": 2, "result": "WA", "execution_time": "1499 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi * 0.6081735, 0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.t(0)\n    qc.tdg(1)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.h(1)\n    qc.tdg(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.sdg(0)\n    qc.s(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7C405141A149", "submission_order": 3, "result": "WA", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.acos(1 / math.sqrt(3)) * 2, 0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.t(0)\n    qc.tdg(1)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.h(1)\n    qc.tdg(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.sdg(0)\n    qc.s(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7C405141A149", "submission_order": 4, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.acos(1 / math.sqrt(3)) * 2.000000002, 0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.t(0)\n    qc.tdg(1)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.h(1)\n    qc.tdg(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.sdg(0)\n    qc.s(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7C405141A149", "submission_order": 5, "result": "WA", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1 / math.sqrt(3)) * 2, 0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.t(0)\n    qc.tdg(1)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.h(1)\n    qc.tdg(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.sdg(0)\n    qc.s(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7C405141A149", "submission_order": 6, "result": "AC", "execution_time": "895 ms", "memory": "91 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1 / math.sqrt(3)) * 2, 0)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.t(0)\n    qc.tdg(1)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.h(1)\n    qc.tdg(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.sdg(0)\n    qc.s(1)\n    qc.crz(math.pi / 2, 0, 1)\n    qc.crz(-math.pi / 2, 1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7D8079FA7971", "submission_order": 1, "result": "AC", "execution_time": "1274 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t = 2 * math.asin(1/math.sqrt(3))\n    qc.ry(t, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7DFA16E94661", "submission_order": 1, "result": "RE", "execution_time": "742 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(math.acos(1/math.sqrt(3))*2, 0)\n    # crx 90\n    qc.ch(0, 1)\n    qc.x(0)\n    # qc.swap(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A7DFA16E94661", "submission_order": 2, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(math.acos(1/math.sqrt(3))*2, 0)\n    # crx 90\n    qc.ch(0, 1)\n    qc.x(0)\n    # qc.swap(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 1, "result": "RE", "execution_time": "950 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1, math.pi/math.sqrt(3))\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 2, "result": "WA", "execution_time": "1066 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.pi/math.sqrt(3),1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 3, "result": "WA", "execution_time": "973 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.pi/math.sqrt(3),1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 4, "result": "WA", "execution_time": "910 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.pi/math.sqrt(3),1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 5, "result": "WA", "execution_time": "1088 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    theta = math.acos(2 / math.sqrt(3) - 0.5)\n    qc.ry(theta,1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 6, "result": "WA", "execution_time": "1015 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    theta = math.acos(2 / math.sqrt(3) - 1)\n    qc.ry(theta,1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 7, "result": "WA", "execution_time": "1019 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    theta = math.acos(2 / math.sqrt(6) - 1)\n    qc.ry(theta,1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 8, "result": "WA", "execution_time": "962 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    theta = math.acos(4 / math.sqrt(6) - 1)\n    qc.ry(theta,1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 9, "result": "WA", "execution_time": "1062 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    theta = math.acos(2 / math.sqrt(3) - 1)\n    qc.ry(theta,1)\n    qc.ch(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 10, "result": "WA", "execution_time": "969 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    theta = math.acos(2 / math.sqrt(3) - 1)\n    qc.ry(theta,1)\n    qc.ch(1,0, ctrl_state=0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 11, "result": "WA", "execution_time": "925 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    theta = math.acos(math.sqrt(2) / math.sqrt(3) - 1)\n    qc.ry(theta,1)\n    qc.ch(1,0, ctrl_state=0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80636FE50D0B", "submission_order": 12, "result": "AC", "execution_time": "1203 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    theta = math.acos(1/3)\n    qc.ry(theta,1)\n    qc.ch(1,0, ctrl_state=0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80A9D144B8E4", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ry\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    phi = acos(sqrt(1/3))\n    qc.ry(2*phi, 0)\n    qc.ch(0,1)\n\n    return qc\n\nfrom qiskit import Aer, transpile, assemble\n\ndef execute_circuit(qc):\n    simulator = Aer.get_backend('statevector_simulator')\n    transpiled_qc = transpile(qc, simulator)\n    qobj = assemble(transpiled_qc)\n    result = simulator.run(qobj).result()\n    statevector = result.get_statevector()\n    return statevector\n\n# 与えられた関数を使用して量子回路を作成\nqc = solve()\n\n# 量子回路をstatevectorで実行して結果を取得\nresult_statevector = execute_circuit(qc)\n\n# 結果の表示\nprint(\"Statevector after execution:\", result_statevector)\n'''"}
{"problem": "QPC001_A5", "user": "A80A9D144B8E4", "submission_order": 2, "result": "WA", "execution_time": "924 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ry\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    phi = acos(sqrt(1/3))\n    qc.ry(2*phi, 0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A80A9D144B8E4", "submission_order": 3, "result": "AC", "execution_time": "897 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ry\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    phi = acos(sqrt(2/3))\n    qc.ry(2*phi, 0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A814BCB2B0442", "submission_order": 1, "result": "AC", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * acos((1 / 3) ** 0.5)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A81E7B343F781", "submission_order": 1, "result": "WA", "execution_time": "1330 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    p0 = math.sqrt(1/3)\n    theta=math.acos(p0*2-1)\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A81E7B343F781", "submission_order": 2, "result": "AC", "execution_time": "1339 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    p0 = 1/3\n    theta=math.acos(p0*2-1)\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A82C537533D12", "submission_order": 1, "result": "WA", "execution_time": "983 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta_0 = math.acos(1 / math.sqrt(3))\n    theta_1 = math.pi / 2\n\n    qc.ry(theta_0, 0)\n    qc.x(0)\n    qc.cry(theta_1, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A82C537533D12", "submission_order": 2, "result": "AC", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta_0 = math.asin(1 / math.sqrt(3)) * 2\n    theta_1 = math.pi / 2\n\n    qc.ry(theta_0, 0)\n    qc.x(0)\n    qc.cry(theta_1, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8392DF289900", "submission_order": 1, "result": "WA", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.ch(0,1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8392DF289900", "submission_order": 2, "result": "RE", "execution_time": "806 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rx(math.pi/3)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8392DF289900", "submission_order": 3, "result": "RE", "execution_time": "781 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),0)\n    # The circuit is now prepared with the desired state |psi⟩\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8392DF289900", "submission_order": 4, "result": "AC", "execution_time": "1482 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),0)\n    # The circuit is now prepared with the desired state |psi⟩\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A84ECDEC8B792", "submission_order": 1, "result": "AC", "execution_time": "967 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(acos(sqrt(2 / 3)) * 2, 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A858305A940D2", "submission_order": 1, "result": "RE", "execution_time": "765 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U3Gate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # 1/sqrt(3) に対応する角度を計算\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    \n    # アダマールゲートを最初の量子ビットに適用して重ね合わせを作成\n    qc.h(0)\n    \n    # 特定の角度で2番目の量子ビットを回転させる\n    qc.u3(theta, 0, 0, 1)\n    \n    # 制御NOTゲートを適用してエンタングルメントを作成\n    qc.cx(0, 1)\n    \n    # 2番目の量子ビットに再度アダマールゲートを適用\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A892AB430B265", "submission_order": 1, "result": "RE", "execution_time": "732 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A892AB430B265", "submission_order": 2, "result": "RE", "execution_time": "818 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A892AB430B265", "submission_order": 3, "result": "RE", "execution_time": "869 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A892AB430B265", "submission_order": 4, "result": "AC", "execution_time": "892 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8B5D33428741", "submission_order": 1, "result": "AC", "execution_time": "868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * atan(sqrt(6) / (3 + sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8B7B0946DE0A", "submission_order": 1, "result": "WA", "execution_time": "946 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 1, "result": "WA", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 2, "result": "WA", "execution_time": "1087 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.rx(pi/12, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 3, "result": "WA", "execution_time": "1412 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.rx(-pi/12, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 4, "result": "WA", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.rx(pi/3, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 5, "result": "WA", "execution_time": "821 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.rz(pi/12, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 6, "result": "WA", "execution_time": "831 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.ry(pi/12, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 7, "result": "WA", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.ry(-pi/12, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 8, "result": "WA", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.rz(-pi/12, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 9, "result": "RE", "execution_time": "921 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u1(pi/3, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 10, "result": "RE", "execution_time": "763 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.u1(pi/12, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 11, "result": "RE", "execution_time": "751 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(pi/3, pi/6, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 12, "result": "RE", "execution_time": "1029 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(pi/2, pi/2, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 13, "result": "RE", "execution_time": "1271 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(pi/, pi/2, qc[1])\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 14, "result": "RE", "execution_time": "755 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(pi/2, pi/2, qc[1])\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 15, "result": "RE", "execution_time": "749 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(math.pi/2, math.pi/2, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 16, "result": "RE", "execution_time": "736 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(1, 0, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 17, "result": "RE", "execution_time": "785 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(pi/3, pi/6, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 18, "result": "RE", "execution_time": "888 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(2*pi/3, pi/3, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 19, "result": "RE", "execution_time": "771 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(2*pi/3, pi/, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A8D812C6DEC57", "submission_order": 20, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.u2(2*pi/3, pi/, 1)\n    qc.ch(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9059141B1D3E", "submission_order": 1, "result": "WA", "execution_time": "1934 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.p(math.pi/3,0)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9059141B1D3E", "submission_order": 2, "result": "WA", "execution_time": "836 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(math.pi*2/3,0)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9059141B1D3E", "submission_order": 3, "result": "WA", "execution_time": "1521 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(math.pi*2/3,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9059141B1D3E", "submission_order": 4, "result": "AC", "execution_time": "1587 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.ry(math.acos(1/math.sqrt(3))*2,1)\n    qc.ch(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A90EA2F2F16AC", "submission_order": 1, "result": "AC", "execution_time": "702 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A918460D0016F", "submission_order": 1, "result": "RE", "execution_time": "843 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    def u3(qc, theta, phi, lam, q):\n        qc.rz(lam, q)\n        qc.rx(math.pi/2, q)\n        qc.rz(theta, q)\n        qc.rx(-math.pi/2, q)\n        qc.rz(phi, q)\n    u3(qc, 2*math.acos(1/math.sqrt(3)), 0, 0, 0)\n    u3(qc,0, 0, -math.pi/2, 1)\n    qc.cx(0,1)\n    u3(qc,math.pi/4, 0, -math.pi/2, 1)\n\n    qc.cx(0,1)\n    u3(qc,math.pi, 0, -math.pi/2, 0)\n    u3(qc,math.pi/4, 0, math.pi, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A918460D0016F", "submission_order": 2, "result": "AC", "execution_time": "2000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    def u3(qc, theta, phi, lam, q):\n        qc.rz(lam, q)\n        qc.rx(math.pi/2, q)\n        qc.rz(theta, q)\n        qc.rx(-math.pi/2, q)\n        qc.rz(phi, q)\n    u3(qc, 2*math.acos(1/math.sqrt(3)), 0, 0, 0)\n    u3(qc,0, 0, -math.pi/2, 1)\n    qc.cx(0,1)\n    u3(qc,math.pi/4, 0, -math.pi/2, 1)\n\n    qc.cx(0,1)\n    u3(qc,math.pi, 0, -math.pi/2, 0)\n    u3(qc,math.pi/4, 0, math.pi, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A923A039D155A", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport math\n\ndef solve() -> QuantumCircuit:\n    # Create a new quantum circuit with 2 qubits\n    qc = QuantumCircuit(2)\n\n    # We need to create a state which is a superposition of |00>, |01>, and |10>\n    # The amplitude for each state should be 1/sqrt(3)\n    \n    # Apply a Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply a rotation to the second qubit, the angle for Y-rotation is acos(1/sqrt(3))\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 1)\n    \n    # Apply controlled-X gate to flip the second qubit if the first qubit is |1>\n    qc.cx(0, 1)\n    \n    # And then, we clean up unnecessary state |11> by using controlled-Z gate\n    qc.cz(0, 1)\n    \n    # Make sure that the amplitudes are correct\n    state = Statevector.from_instruction(qc)\n    assert math.isclose(abs(state[0b00]), 1/math.sqrt(3), abs_tol=1e-10)\n    assert math.isclose(abs(state[0b01]), 1/math.sqrt(3), abs_tol=1e-10)\n    assert math.isclose(abs(state[0b10]), 1/math.sqrt(3), abs_tol=1e-10)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A923A039D155A", "submission_order": 2, "result": "WA", "execution_time": "947 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    # 2量子ビットの量子回路を初期化\n    qc = QuantumCircuit(2)\n\n    # 状態|00>+|10>+|01>を生成するには、まず第一ビットに重ね合わせを作る\n    qc.h(0) # Hadamard gate on the first qubit\n\n    # 次に、第二ビットに特定の角度でローテーションを適用する\n    # 第一ビットが|1>のときのみ、第二ビットにローテーションを適用するため、制御ゲートを使う\n    theta = 2 * math.acos(1 / math.sqrt(3)) # この角度は、状態|0>と|1>の振幅比が1:√2になるように計算される\n    qc.ry(theta, 1) # Rotate-y gate with calculated theta on the second qubit\n\n    # CRyゲートを使って制御したYローテーションを第二ビットに適用\n    qc.cry(-theta / 2, 0, 1) # Controlled-Ry gate with -theta/2 on the control qubit 0 and target qubit 1\n\n    # 最後に、第一ビットに再びHadamardゲートを適用する\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A923A039D155A", "submission_order": 3, "result": "WA", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef create_uniform_superposition(qc, qubit, num_states):\n    \"\"\"Create a uniform superposition of num_states on qubit in qc.\"\"\"\n    angle = 2 * math.asin(math.sqrt(1 / num_states))\n    qc.ry(angle, qubit)\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Apply a rotation to the first qubit to get it in the state (|0⟩ + √2|1⟩) / √3\n    create_uniform_superposition(qc, 0, 3)\n\n    # Add a CNOT gate to entangle with the second qubit\n    qc.cx(0, 1)\n    \n    # Now perform a corrective rotation on the second qubit if needed\n    qc.ry(-math.pi/4, 1)\n    qc.cx(0, 1)\n    qc.ry(math.pi/4, 1)\n\n    return qc\n\n# Uncomment below to test the solve() function\n# circuit = solve()\n# print(circuit)\n'''"}
{"problem": "QPC001_A5", "user": "A923A039D155A", "submission_order": 4, "result": "AC", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom math import sqrt, acos\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = 2 * acos(sqrt(1/3))\n    theta2 = 2 * acos(sqrt(1/2))\n\n    qc.ry(theta, 0)\n    qc.cry(theta2, 0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A92B6CB95A86D", "submission_order": 1, "result": "WA", "execution_time": "1643 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A92B6CB95A86D", "submission_order": 2, "result": "WA", "execution_time": "1004 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.asin(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A92B6CB95A86D", "submission_order": 3, "result": "AC", "execution_time": "870 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.asin(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A94ADDA1FB1F2", "submission_order": 1, "result": "AC", "execution_time": "1652 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(4 * math.atan(math.sqrt(2) / (math.sqrt(3) + 1)), 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A97C3430A6D4F", "submission_order": 1, "result": "WA", "execution_time": "1201 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.2310,0)\n    qc.ry(0.785398,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-0.785398,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A97C3430A6D4F", "submission_order": 2, "result": "AC", "execution_time": "1301 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos((2/3)**(1/2))\n    qc.ry(theta,0)\n    qc.ry(math.pi / 4,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-math.pi / 4,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A98526C76B400", "submission_order": 1, "result": "AC", "execution_time": "1810 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \nn = 2\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    theta = math.acos(math.sqrt(2)/math.sqrt(3))*2\n    qc.ry(theta, 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9864B4B322A9", "submission_order": 1, "result": "WA", "execution_time": "1027 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.rx(acos(1/sqrt(3)), 0)\n    qc.s(1)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9864B4B322A9", "submission_order": 2, "result": "WA", "execution_time": "952 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.rx(acos(1/sqrt(3)), 0)\n    qc.s(0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9864B4B322A9", "submission_order": 3, "result": "WA", "execution_time": "888 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.rx(acos(1/sqrt(3))/2, 0)\n    qc.s(0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9864B4B322A9", "submission_order": 4, "result": "WA", "execution_time": "1538 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.rx(acos(1/sqrt(3))*2, 0)\n    qc.s(0)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9864B4B322A9", "submission_order": 5, "result": "WA", "execution_time": "1647 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.rx(acos(1/sqrt(3))*2, 0)\n    qc.s(0)\n    qc.ch(0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9864B4B322A9", "submission_order": 6, "result": "AC", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.rx(acos(1/sqrt(3))*2, 0)\n    qc.s(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A999EB88292C6", "submission_order": 1, "result": "WA", "execution_time": "1452 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.rx(np.arcsin(np.sqrt(2/3)),1)\n    qc.ch(1,0)\n    qc.x(1)\n    qc.rz(np.pi/4,1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 1, "result": "RE", "execution_time": "1433 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.arcsin(2*math.sqrt(3))*2\n    qc.r(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 2, "result": "RE", "execution_time": "1429 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.arcsin(2*math.sqrt(3))*2\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 3, "result": "RE", "execution_time": "1372 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.arcsin(2*math.sqrt(3))/2\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 4, "result": "RE", "execution_time": "1327 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.arcsin(math.sqrt(2/3))/2\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 5, "result": "RE", "execution_time": "1411 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.asin(math.sqrt(2/3))/2\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 6, "result": "RE", "execution_time": "1405 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.asi(math.sqrt(2/3))/2\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 7, "result": "RE", "execution_time": "1370 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.asi(math.sqrt(2/3))*2\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 8, "result": "RE", "execution_time": "1453 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.asi(math.sqrt(2/3))*2\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9A7C19B0F548", "submission_order": 9, "result": "AC", "execution_time": "1498 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta= math.asin(math.sqrt(2/3))*2\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9B8C7F8F2F80", "submission_order": 1, "result": "WA", "execution_time": "831 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1 / (3 ** 0.5))\n    qc.rx(theta, 1)\n    qc.ch(1, 0)\n    qc.cp(-math.pi / 4, 1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9B8C7F8F2F80", "submission_order": 2, "result": "RE", "execution_time": "830 ms", "memory": "79 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(-2 / (3 ** 0.5))\n    qc.rx(theta, 1)\n    qc.ch(1, 0)\n    qc.cp(-math.pi / 4, 1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9B8C7F8F2F80", "submission_order": 3, "result": "WA", "execution_time": "838 ms", "memory": "91 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1 / (3 ** 0.5))\n    qc.rx(-2 * theta, 1)\n    qc.ch(1, 0)\n    qc.cp(-math.pi / 4, 1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9B8C7F8F2F80", "submission_order": 4, "result": "AC", "execution_time": "818 ms", "memory": "91 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1 / (3 ** 0.5))\n    qc.rx(-2 * theta, 1)\n    qc.x(0)\n    qc.cp(-math.pi / 2, 1, 0)\n    qc.x(0)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9D4C3B871CAA", "submission_order": 1, "result": "WA", "execution_time": "1415 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9D4C3B871CAA", "submission_order": 2, "result": "UGE", "execution_time": "1418 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.initialize([1/math.sqrt(3), 1/math.sqrt(3), 1/math.sqrt(3),0], [0,1])\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9D4C3B871CAA", "submission_order": 3, "result": "RE", "execution_time": "988 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.arccos(1/math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "A9D4C3B871CAA", "submission_order": 4, "result": "AC", "execution_time": "1045 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1/math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA065160F417B", "submission_order": 1, "result": "AC", "execution_time": "914 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA0CADF33C5C2", "submission_order": 1, "result": "UGE", "execution_time": "746 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    init = [\n        1/math.sqrt(3)*complex(1,0),\n        1/math.sqrt(3)*complex(1,0),\n        1/math.sqrt(3)*complex(1,0),\n        0\n    ]\n    qc.initialize(init, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA0CADF33C5C2", "submission_order": 2, "result": "RE", "execution_time": "794 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4*atan(math.sqrt(6)/(3+math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA0CADF33C5C2", "submission_order": 3, "result": "AC", "execution_time": "852 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA26FAE9E19B8", "submission_order": 1, "result": "RE", "execution_time": "1352 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(t,0)\n    qc.rh(0,1)\n    qx.rx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA26FAE9E19B8", "submission_order": 2, "result": "RE", "execution_time": "1403 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve()->QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(t,0)\n    qc.ch(0,1)\n    qx.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA26FAE9E19B8", "submission_order": 3, "result": "RE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve()->QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(t,0)\n    qc.ch(0,1)\n    qx.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA26FAE9E19B8", "submission_order": 4, "result": "AC", "execution_time": "1404 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve()->QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(t,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA2D1F548E61D", "submission_order": 1, "result": "RE", "execution_time": "759 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    d = 1 / math.sqrt(3)\n    mat = [\n        [d, 0, 0, 0],\n        [d, 0, 0, 0],\n        [d, 0, 0, 0],\n        [0, 0, 0, 0]\n    ]\n    qc.unitary(mat, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA2D1F548E61D", "submission_order": 2, "result": "UGE", "execution_time": "786 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    d = 1 / math.sqrt(3)\n    mat = [\n        [0, d, d, d],\n        [d, d, 0, -d],\n        [d, 0, -d, d],\n        [d, -d, d, 0]\n    ]\n    qc.unitary(mat, [0, 1])\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA494346E5E61", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.extensions import UnitaryGate\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # 2量子ビットでのカスタムユニタリ変換を定義\n    # この変換は状態 |00> を (|00> + |10> + |01>) / sqrt(3) にマッピングする\n    u_matrix = np.array([\n        [1/np.sqrt(3), 0, 0, 0],\n        [1/np.sqrt(3), 0, 0, 0],\n        [1/np.sqrt(3), 0, 0, 0],\n        [0, 1, 0, 0]\n    ])\n\n    # カスタムユニタリゲートを適用\n    qc.append(UnitaryGate(u_matrix), [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA56A3D47D0C0", "submission_order": 1, "result": "WA", "execution_time": "1919 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.h(1)\n    qc.rz(2 * pi / 3, 0)\n    qc.rz(2 * pi / 3, 1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA56A3D47D0C0", "submission_order": 2, "result": "WA", "execution_time": "1897 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply a controlled rotation to create the correct superposition\n    # We can use a combination of RX and RY gates to adjust the amplitudes\n    # to achieve the desired state.\n    \n    # Apply a rotation to the second qubit\n    qc.ry(2 * math.acos(1 / math.sqrt(3)), 1)  # Rotate second qubit\n    \n    # Apply a controlled NOT gate to entangle the qubits\n    qc.cx(0, 1)  # CNOT from qubit 0 to qubit 1\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA56A3D47D0C0", "submission_order": 3, "result": "AC", "execution_time": "1962 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    theta = 2 * math.atan2(math.sqrt(2/3),math.sqrt(1/3))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AA77C87939F89", "submission_order": 1, "result": "AC", "execution_time": "1620 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1/math.sqrt(3))*2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 1, "result": "RE", "execution_time": "835 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.arccos(1/math.sqrt(3)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2, 0, 1)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 2, "result": "RE", "execution_time": "827 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2, 0, 1)\n    qc.x(0)\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 3, "result": "RE", "execution_time": "762 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.arcos(1/math.sqrt(3)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2, 0, 1)\n    qc.x(0)\n    qc.x(1))\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 4, "result": "RE", "execution_time": "756 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.arcos(1/math.sqrt(3)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2, 0, 1)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 5, "result": "WA", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2, 0, 1)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 6, "result": "WA", "execution_time": "849 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2, 0, 1)\n    qc.x(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 7, "result": "WA", "execution_time": "989 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2.0*math.acos(1.0/math.sqrt(3.0)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2.0, 0, 1)\n    qc.x(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 8, "result": "WA", "execution_time": "1082 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2.0*math.acos(1.0/math.sqrt(3.0)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2.0, 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAD883C72D1B8", "submission_order": 9, "result": "AC", "execution_time": "874 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2.0*math.acos(1.0/math.sqrt(3.0)), 0)\n    qc.x(1)\n    qc.cry(math.pi/2.0, 0, 1)\n    qc.x(1)\n    qc.x(0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAE5ABF777857", "submission_order": 1, "result": "WA", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAE5ABF777857", "submission_order": 2, "result": "RE", "execution_time": "1536 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 math.atan((1-math.sqrt(2))/(1+math.sqrt(2)))\n    qc.ry(theta)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    qc.ch(0,1)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAE5ABF777857", "submission_order": 3, "result": "RE", "execution_time": "1435 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan((1-math.sqrt(2))/(1+math.sqrt(2)))\n    qc.ry(theta)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    qc.ch(0,1)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAE5ABF777857", "submission_order": 4, "result": "RE", "execution_time": "766 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import RYGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan((1-math.sqrt(2))/(1+math.sqrt(2)))\n    qc.append(\n        ry(theta), \n        [0]\n    )\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    qc.ch(0,1)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAE5ABF777857", "submission_order": 5, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import RYGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan((1-math.sqrt(2))/(1+math.sqrt(2)))\n    qc.append(\n        RYGate(theta), \n        [0]\n    )\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    qc.ch(0,1)\n    qc.ch(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAF7DB4C993D7", "submission_order": 1, "result": "RE", "execution_time": "2015 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = math.atan(math.sqrt(2)) * 2\n    qc.ry(theta)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAF7DB4C993D7", "submission_order": 2, "result": "RE", "execution_time": "1831 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = math.atan(math.sqrt(2)) * 2\n    qc.ry(0, theta)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AAF7DB4C993D7", "submission_order": 3, "result": "AC", "execution_time": "1962 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = math.atan(math.sqrt(2)) * 2\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB3EF6DF6F1ED", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n#from qiskit_ibm_runtime import QiskitRuntimeService, Sampler\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = np.arccos(1/np.sqrt(3))\n    qc.ry(theta*2,0)\n    theta2 = np.arccos(1/np.sqrt(2))\n    qc.cry(theta2*2,0,1)\n    # qc.measure_all()\n\n    # service = QiskitRuntimeService()\n    # backend = service.backend(\"ibmq_qasm_simulator\")\n    # job = Sampler(backend).run(qc)\n    # print(f\"job id: {job.job_id()}\")\n    # result = job.result()\n    # print(result)\n    return qc\n#solve()\n'''"}
{"problem": "QPC001_A5", "user": "AB3EF6DF6F1ED", "submission_order": 2, "result": "WA", "execution_time": "1569 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit_ibm_runtime import QiskitRuntimeService, Sampler\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1/math.sqrt(3))\n    qc.ry(theta*2,0)\n    theta2 = math.acos(1/math.sqrt(2))\n    qc.cry(theta2*2,0,1)\n    # qc.measure_all()\n\n    # service = QiskitRuntimeService()\n    # backend = service.backend(\"ibmq_qasm_simulator\")\n    # job = Sampler(backend).run(qc)\n    # print(f\"job id: {job.job_id()}\")\n    # result = job.result()\n    # print(result)\n    return qc\n#solve()\n'''"}
{"problem": "QPC001_A5", "user": "AB3EF6DF6F1ED", "submission_order": 3, "result": "AC", "execution_time": "907 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit_ibm_runtime import QiskitRuntimeService, Sampler\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.asin(1/math.sqrt(3))\n    qc.ry(theta*2,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    # qc.measure_all()\n\n    # service = QiskitRuntimeService()\n    # backend = service.backend(\"ibmq_qasm_simulator\")\n    # job = Sampler(backend).run(qc)\n    # print(f\"job id: {job.job_id()}\")\n    # result = job.result()\n    # print(result)\n    return qc\n#solve()\n'''"}
{"problem": "QPC001_A5", "user": "AB511AB09B475", "submission_order": 1, "result": "RE", "execution_time": "1454 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a = 4 * math.atan(math.sqrt(2)/(math.sqrt(3) + 1))\n    qc.ry(a,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB511AB09B475", "submission_order": 2, "result": "AC", "execution_time": "1448 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    a = 4 * math.atan(math.sqrt(2)/(math.sqrt(3) + 1))\n    qc.ry(a,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB54A1FCDDBC6", "submission_order": 1, "result": "WA", "execution_time": "1212 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB58BC06619B1", "submission_order": 1, "result": "WA", "execution_time": "925 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * atan(sqrt(6) / (3 + sqrt(3)))\n    qc.ry(theta,0)\n    qc.h(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB58BC06619B1", "submission_order": 2, "result": "AC", "execution_time": "957 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * atan(sqrt(6) / (3 + sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB75836A1C5E1", "submission_order": 1, "result": "UGE", "execution_time": "774 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    import math\n\n    qc.prepare_state([1 / math.sqrt(3),1 / math.sqrt(3),1 / math.sqrt(3),0], qc.qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB924623AEF8B", "submission_order": 1, "result": "AC", "execution_time": "1402 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB9E529B579F7", "submission_order": 1, "result": "RE", "execution_time": "1497 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AB9E529B579F7", "submission_order": 2, "result": "AC", "execution_time": "1587 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA1B2AE2C5AB", "submission_order": 1, "result": "AC", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    \n    prob_amp = math.sqrt(1 / 3)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 0, 1)\n    qc.cx(1, 0)\n\n    prob_amp = math.sqrt(1 / 2)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 1, 0)\n    \n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 1, "result": "WA", "execution_time": "1131 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 2, "result": "RE", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*np.pi/3,0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 3, "result": "WA", "execution_time": "1343 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(-1/3,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 4, "result": "WA", "execution_time": "1365 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1/3*2-1,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 5, "result": "RE", "execution_time": "1350 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = theta=math.acos(1/3*2-1)\n    qc.ry(angle,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 6, "result": "RE", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = math.acos(1/3*2-1)\n    qc.ry(angle,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 7, "result": "RE", "execution_time": "1347 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = math.acos(-1/3)\n    qc.ry(angle,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 8, "result": "RE", "execution_time": "1328 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = math.acos(1/3*2-1)\n    qc.ry(angle,1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 9, "result": "RE", "execution_time": "1333 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2*math.acos(1/1.73)\n    qc.ry(angle,1)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 10, "result": "RE", "execution_time": "1337 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2*math.acos(1/np.sqrt(3))\n    qc.ry(angle,1)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 11, "result": "WA", "execution_time": "1367 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2*np.arccos(1/np.sqrt(3))\n    qc.ry(angle,0)\n    qc.z(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABA82C21D9FCE", "submission_order": 12, "result": "AC", "execution_time": "1451 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2*np.arccos(1/np.sqrt(3))\n    qc.ry(angle,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABB874E3E4A58", "submission_order": 1, "result": "AC", "execution_time": "874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import asin,sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*asin(sqrt(6)/3),0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABE38AACF1859", "submission_order": 1, "result": "RE", "execution_time": "800 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    # 各量子ビットにHゲートを適用\n    qc.h(0)\n    qc.h(1)\n\n    # 制御回転ゲートを使用して均等な振幅を持たせる\n    qc.cu3(2 * 1/3, 0, 0, 0, 1)  # 制御U3ゲートを使用して均等な振幅を持たせる\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ABF7E356D8572", "submission_order": 1, "result": "AC", "execution_time": "984 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC37C0F07D4BD", "submission_order": 1, "result": "RE", "execution_time": "742 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(2/3) * 2)\n    qc.ry(theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC37C0F07D4BD", "submission_order": 2, "result": "AC", "execution_time": "1384 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(2/3)) * 2\n    qc.ry(theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC402199E70F2", "submission_order": 1, "result": "AC", "execution_time": "957 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import asin, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = asin(1 / sqrt(3))\n    qc.ry(theta * 2, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC4271484DB4F", "submission_order": 1, "result": "WA", "execution_time": "1730 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1 / (math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC4271484DB4F", "submission_order": 2, "result": "AC", "execution_time": "1758 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.acos(1 / (math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC5142CB32547", "submission_order": 1, "result": "RE", "execution_time": "1336 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Step 1: Put q0 into the right superposition (use Ry rotation)\n    theta = 2 * np.arccos(1 / np.sqrt(3))\n    qc.ry(theta, 0)\n    # Step 2: Use CNOT to distribute amplitude to |01>\n    qc.cx(0, 1)\n    # Step 3: Prepare the superposition on q1 when q0 is 0\n    phi = 2 * np.arccos(np.sqrt(2/3))\n    qc.cry(phi, 0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC5142CB32547", "submission_order": 2, "result": "RE", "execution_time": "1492 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta_q0 = 2 * np.arccos(np.sqrt(2/3))\n    qc.ry(theta_q0, 0) # Apply Ry gate to qubit 0\n    qc.cry(np.pi / 2, 0, 1) # Apply controlled-Ry(pi/2) with control qubit 0 and target qubit 1\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC5142CB32547", "submission_order": 3, "result": "RE", "execution_time": "1504 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * np.arccos(np.sqrt(2/3))\n    qc.ry(theta, 0)\n    \n    # Step 2: Controlled operation on second qubit\n    # When qubit 0 is |0⟩: we want equal superposition (1/√2)(|0⟩ + |1⟩)\n    # When qubit 0 is |1⟩: we want qubit 1 to stay in |0⟩\n    \n    # Apply controlled Hadamard with inverted control\n    qc.x(0)  # Flip qubit 0 to invert control\n    qc.ch(0, 1)  # Controlled Hadamard: applies H to qubit 1 when qubit 0 is |1⟩\n    qc.x(0)  # Flip qubit 0 back\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC5142CB32547", "submission_order": 4, "result": "RE", "execution_time": "1476 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Apply Hadamard to the first qubit\n    qc.h(0)\n    # Apply a controlled rotation to create the desired amplitudes\n    theta = 2 * np.arccos(np.sqrt(2/3))\n    qc.ry(theta, 1)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.ry(-theta, 1)\n    qc.x(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC5FE92B7AC51", "submission_order": 1, "result": "AC", "execution_time": "1644 ms", "memory": "142 MiB", "code": "'''python\nfrom math import pi, sqrt\nfrom numpy import arccos, arcsin\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = arccos(sqrt(1 / 3)) * 2\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC60B30C859AE", "submission_order": 1, "result": "AC", "execution_time": "1417 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\nfrom qiskit import QuantumCircuit\n#from qiskit.quantum_info import Statevector\nimport numpy as np\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = np.arccos(1/np.sqrt(3))*2\n    qc.rx(theta,0)\n    qc.p(np.pi/2,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n    \nqc = solve()\nprint(qc)\n#print(Statevector(qc))\n'''"}
{"problem": "QPC001_A5", "user": "AC680A2AF9871", "submission_order": 1, "result": "RE", "execution_time": "785 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(3))\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC6D539921257", "submission_order": 1, "result": "AC", "execution_time": "1775 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1/math.sqrt(3)) * 2\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.cry(-math.pi/2, 0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC6F990EA1261", "submission_order": 1, "result": "AC", "execution_time": "1110 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc .cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AC777AD41D58A", "submission_order": 1, "result": "AC", "execution_time": "1465 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef rotate(qc,p0,index):\n    theta=math.acos(p0*2-1)\n    qc.ry(theta,index)\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    rotate(qc,1/3,1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACADFDC12E2FC", "submission_order": 1, "result": "RE", "execution_time": "744 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACADFDC12E2FC", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACADFDC12E2FC", "submission_order": 3, "result": "AC", "execution_time": "791 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACB995DA2388E", "submission_order": 1, "result": "RE", "execution_time": "1372 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACB995DA2388E", "submission_order": 2, "result": "WA", "execution_time": "1586 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACBA1C59A57E0", "submission_order": 1, "result": "AC", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef one2one(bit_org: int, bit: int, n_qubits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    b = 1\n    bit_dif = bit_org ^ bit\n    for i in range(n_qubits):\n        if (bit_dif&b) > 0:\n            qc.x(i)\n        b *= 2\n    return qc\n\ndef one2two(bit_org: int, bit1: int, bit2: int, n_qubits: int) -> QuantumCircuit:\n    if bit1==bit2:\n        return one2one(bit_org, bit1, n_qubits)\n    qc = QuantumCircuit(n_qubits)\n    bit1_dif = bit_org ^ bit1\n    bit2_dif = bit_org ^ bit2\n    dif_common = bit1_dif & bit2_dif\n    dif_dif = bit1_dif ^ bit2_dif\n    if dif_common == bit2_dif:\n        bit1, bit2 = bit2, bit1\n        bit1_dif, bit2_dif = bit2_dif, bit1_dif\n    b = 1\n    bit2_dif_last = -1\n    for i in range(n_qubits):\n        if (dif_common&b)>0:\n            qc.x(i)\n        if ((dif_dif&bit2_dif)&b)>0:\n            bit2_dif_last = i\n        b *= 2\n    if (1<<bit2_dif_last)&bit_org > 0:\n        qc.x(bit2_dif_last)\n    qc.h(bit2_dif_last)\n    if (1<<bit2_dif_last)&bit_org > 0:\n        qc.x(bit2_dif_last)\n    b = 1\n    for i in range(n_qubits):\n        if ((dif_dif&bit1_dif)&b)>0:\n            qc.cx(bit2_dif_last, i)\n        b *= 2\n    qc.x(bit2_dif_last)\n    b = 1\n    for i in range(n_qubits):\n        if ((dif_dif&bit2_dif)&b)>0 and i != bit2_dif_last:\n            qc.cx(bit2_dif_last, i)\n        b *= 2\n    if (1<<bit2_dif_last)&bit_org > 0:\n        qc.x(bit2_dif_last)\n    return qc\n\ndef one2three(bit_org: int, bit1: int, bit2: int, bit3: int, n_qubits: int) -> QuantumCircuit:\n    if bit1 == bit2 == bit3:\n        return one2one(bit_org, bit1, n_qubits)\n    \n    qc = QuantumCircuit(n_qubits)\n    b = 1\n    for i in range(n_qubits):\n        if (b&bit_org) > 0:\n            qc.x(i)\n        b *= 2\n\n    b = 1\n    for i in range(n_qubits):\n        if not ((b&bit1) == (b&bit2) == (b&bit3)):\n            if (b&bit1) == (b&bit2):\n                bit1, bit3 = bit3, bit1\n            elif (b&bit1) == (b&bit3):\n                bit1, bit2 = bit2, bit1\n            bit1ctrl = i\n            bit1ctrlsgn = ((bit1&b) > 0)\n            if bit1ctrlsgn:\n                qc.ry(2*math.acos((2/3)**0.5), bit1ctrl)            \n            else:\n                qc.ry(2*math.acos((1/3)**0.5), bit1ctrl)            \n            break\n        b *= 2\n\n    if not bit1ctrlsgn:\n        qc.x(bit1ctrl)    \n    b = 1\n    for i in range(n_qubits):\n        if (b&bit1) > 0 and i != bit1ctrl:\n            qc.cx(bit1ctrl, i)\n        b *= 2\n    if not bit1ctrlsgn:\n        qc.x(bit1ctrl)\n\n    if bit1ctrlsgn:\n        qc.x(bit1ctrl)\n    if bit2 == bit3:\n        b = 1\n        for i in range(n_qubits):\n            if (bit2&b) > 0 and i != bit1ctrl:\n                qc.cx(bit1ctrl, i)\n            b *= 2\n    else:\n        b = 1\n        for i in range(n_qubits):\n            if (bit2&b) != (bit3&b) and i != bit1ctrl:\n                qc.ch(bit1ctrl, i)\n                if (bit2&b) == 0:\n                    bit2, bit3 = bit3, bit2\n                bit2ctrl = i\n                break\n            b *= 2\n        b = 1\n        for i in range(n_qubits):\n            if (bit2&b) > 0 and i != bit2ctrl and i != bit1ctrl:\n                qc.ccx(bit1ctrl, bit2ctrl, i)\n            b *= 2\n        qc.cx(bit1ctrl, bit2ctrl)\n        b = 1\n        for i in range(n_qubits):\n            if (bit3&b) > 0 and i!=bit2ctrl and i != bit1ctrl:\n                qc.ccx(bit1ctrl, bit2ctrl, i)\n            b *= 2\n        qc.cx(bit1ctrl, bit2ctrl)\n    if bit1ctrlsgn:\n        qc.x(bit1ctrl)\n    return qc\ndef solve() -> QuantumCircuit:\n    qc = one2three(0, 0, 1, 2, 2)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACCF712E594F9", "submission_order": 1, "result": "WA", "execution_time": "1885 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.rx(2 * pi/3, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACCF712E594F9", "submission_order": 2, "result": "WA", "execution_time": "1916 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.rx(acos(-1/3), 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACCF712E594F9", "submission_order": 3, "result": "WA", "execution_time": "1935 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.rx(acos(-1/3), 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACCF712E594F9", "submission_order": 4, "result": "WA", "execution_time": "2101 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.rx(acos(-1/3) / 2, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACCF712E594F9", "submission_order": 5, "result": "UGE", "execution_time": "1872 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.prepare_state([1/sqrt(3), sqrt(2/3)], 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACCF712E594F9", "submission_order": 6, "result": "WA", "execution_time": "2012 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.rx(1.91063323624901855632771420503151550848682939002001098191939625864382409180, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACCF712E594F9", "submission_order": 7, "result": "WA", "execution_time": "1780 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.rx(1.91063323624901855632771420503151550848682939002001098191939625864382409180 / 2, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACCF712E594F9", "submission_order": 8, "result": "AC", "execution_time": "1839 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.ry(1.91063323624901855632771420503151550848682939002001098191939625864382409180, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ACE336D7881C1", "submission_order": 1, "result": "AC", "execution_time": "912 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(math.sqrt(1/3)) * 2\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD020AB822791", "submission_order": 1, "result": "AC", "execution_time": "1442 ms", "memory": "142 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve():\n    qc = QuantumCircuit(2)\n    theta = math.acos(math.sqrt(2.0/3.0))*2\n\n    qc.ry(theta, 1)\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.x(1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD0A64D390FE9", "submission_order": 1, "result": "RE", "execution_time": "739 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.231,0)\n    qc.ry(math.p/4,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-math.pi/4,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD0A64D390FE9", "submission_order": 2, "result": "RE", "execution_time": "781 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),0)\n    qc.ry(math.p/4,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-math.pi/4,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD0A64D390FE9", "submission_order": 3, "result": "RE", "execution_time": "810 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),0)\n    qc.ry(math.pi/4,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-math.pi/4,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD0A64D390FE9", "submission_order": 4, "result": "RE", "execution_time": "1677 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),0)\n    qc.ry(math.pi/4,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-math.pi/4,1)\n    qc.measure_all()\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD0A64D390FE9", "submission_order": 5, "result": "RE", "execution_time": "774 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)),0)\n    qc.ry(math.pi/4,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.ry(-math.pi/4,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD0DE1D54A49E", "submission_order": 1, "result": "RE", "execution_time": "1658 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * arcsin(sqrt(1/3))\n    qc.ry(theta,1)\n\n    qc.x(1)\n    qc.cry(math.pi/2,1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD0DE1D54A49E", "submission_order": 2, "result": "AC", "execution_time": "1999 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom numpy import arcsin, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * arcsin(sqrt(1/3))\n    qc.ry(theta,1)\n\n    qc.x(1)\n    qc.cry(math.pi/2,1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD12AAC8F75F4", "submission_order": 1, "result": "RE", "execution_time": "1315 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1 / math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD12AAC8F75F4", "submission_order": 2, "result": "WA", "execution_time": "1454 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1 / math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD12AAC8F75F4", "submission_order": 3, "result": "AC", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(1 / math.sqrt(3)) * 2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD445B91A85F6", "submission_order": 1, "result": "WA", "execution_time": "1725 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.ry(2 * np.arctan(np.sqrt(1/2)), 1)\n    qc.cry(2 * np.arctan(np.sqrt(1/1)), 1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD445B91A85F6", "submission_order": 2, "result": "WA", "execution_time": "1761 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.ry(2 * np.arctan(np.sqrt(2/1)), 1)\n    qc.cry(2 * np.arctan(np.sqrt(1/1)), 1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD445B91A85F6", "submission_order": 3, "result": "WA", "execution_time": "1794 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.ry(2 * np.arctan(np.sqrt(2/1)), 0)\n    qc.cry(2 * np.arctan(np.sqrt(1/1)), 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD445B91A85F6", "submission_order": 4, "result": "AC", "execution_time": "1743 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * np.arctan(np.sqrt(2/1)), 0)\n    qc.cry(2 * np.arctan(np.sqrt(1/1)), 0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD49E60751CE6", "submission_order": 1, "result": "AC", "execution_time": "1925 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.atan(math.sqrt(2)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD58C95C858E3", "submission_order": 1, "result": "AC", "execution_time": "1057 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.2309594185, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD63E0E0C73F9", "submission_order": 1, "result": "AC", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = math.asin(1.0 / math.sqrt(3.0))\n    qc.ry(2.0 * theta, 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD80E92C1EBCE", "submission_order": 1, "result": "RE", "execution_time": "1553 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD80E92C1EBCE", "submission_order": 2, "result": "AC", "execution_time": "1556 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 1, "result": "RE", "execution_time": "800 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(pi/10)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 2, "result": "RE", "execution_time": "848 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(pi/9)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 3, "result": "RE", "execution_time": "982 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    gate = np.array[[1/np.sqrt(3),0,0,0],[0,1/np.sqrt(3),0,0],\n                    [0,0,1/np.sqrt(3),0],[0,0,0,0]]\n    gate.to_gate()\n    qc.append(gate,[0,1])\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 4, "result": "RE", "execution_time": "806 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(pi * 2/3)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 5, "result": "RE", "execution_time": "912 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))))\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 6, "result": "RE", "execution_time": "1269 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))))\n    qc.ch(0,1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 7, "result": "RE", "execution_time": "1262 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))))\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 8, "result": "RE", "execution_time": "1140 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))), 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 9, "result": "RE", "execution_time": "901 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    tanh = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(tanh, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8A23F0C0601", "submission_order": 10, "result": "AC", "execution_time": "1409 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    tanh = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(tanh, 0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    # theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    # qc.ry(theta, 0)\n    # qc.ch(0, 1)\n    # qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD8B73CF2ECCC", "submission_order": 1, "result": "AC", "execution_time": "889 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(2))\n    print(theta)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD90CA22B4F55", "submission_order": 1, "result": "RE", "execution_time": "740 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = acos(sqrt(2/3))\n    if theta < 0:\n        theta = theta*-1\n    qc.ry(theta,1)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD90CA22B4F55", "submission_order": 2, "result": "WA", "execution_time": "1752 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = math.acos(math.sqrt(2/3))\n    if theta < 0:\n        theta = theta*-1\n    qc.ry(theta,1)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD90CA22B4F55", "submission_order": 3, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = 2*math.acos(math.sqrt(2/3))\n    if theta < 0:\n        theta = theta*-1\n    qc.ry(theta,1)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD90CA22B4F55", "submission_order": 4, "result": "AC", "execution_time": "870 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = 2*math.acos(math.sqrt(2/3))\n    if theta < 0:\n        theta = theta*-1\n    qc.ry(theta,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD974EE886B09", "submission_order": 1, "result": "RE", "execution_time": "826 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1/math.sqrt(3))\n    qc.u(theta, 0, 0, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD974EE886B09", "submission_order": 2, "result": "WA", "execution_time": "1454 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1/math.sqrt(3))\n    qc.u(theta, 0, 0, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AD974EE886B09", "submission_order": 3, "result": "AC", "execution_time": "1182 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.acos(1/math.sqrt(3))*2\n    qc.u(theta, 0, 0, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ADFB488C83B19", "submission_order": 1, "result": "RE", "execution_time": "1088 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "ADFB488C83B19", "submission_order": 2, "result": "AC", "execution_time": "1164 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE342EC770D6C", "submission_order": 1, "result": "RE", "execution_time": "1277 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(np.arccos(np.sqrt(2/3)),0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE342EC770D6C", "submission_order": 2, "result": "RE", "execution_time": "1284 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(numpy.arccos(numpy.sqrt(2/3)),0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE342EC770D6C", "submission_order": 3, "result": "RE", "execution_time": "1277 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(sqrt(2/3),0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE342EC770D6C", "submission_order": 4, "result": "RE", "execution_time": "1259 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(2/3)),0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE342EC770D6C", "submission_order": 5, "result": "WA", "execution_time": "1312 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(2/3)),0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE342EC770D6C", "submission_order": 6, "result": "WA", "execution_time": "1297 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(1/3)),0)\n    qc.ry(math.acos(math.sqrt(1/3)),1)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE342EC770D6C", "submission_order": 7, "result": "WA", "execution_time": "1309 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(1/3)),0)\n    qc.ry(math.acos(math.sqrt(1/3)),1)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE342EC770D6C", "submission_order": 8, "result": "WA", "execution_time": "1310 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(1/3)),0)\n    qc.ry(math.acos(math.sqrt(1/3)),1)\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE40BB2849759", "submission_order": 1, "result": "AC", "execution_time": "930 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(0)\n    qc.ry(2 * math.atan2(1, math.sqrt(2)), 1)\n    qc.ch(1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE44BA7C4DEED", "submission_order": 1, "result": "RE", "execution_time": "698 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.ch(1, 1)\n    return qc\n\n## 00\n## 0(0+1)\n## 00 01\n## 00+10+11\n## 00+10+01\n'''"}
{"problem": "QPC001_A5", "user": "AE466B2E91C38", "submission_order": 1, "result": "AC", "execution_time": "818 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt, pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2*acos(1/sqrt(3))\n    qc.cry(theta, 0, 1)\n    qc.x(0)\n    qc.swap(0,1)\n    theta2 = pi/3\n    qc.x(0)\n    qc.cry(theta2,0,1)\n    qc.x(0)\n    qc.ch(1,0)\n    qc.x(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE5A48963AC3B", "submission_order": 1, "result": "UGE", "execution_time": "800 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n\n    # URL: https://qiskit.org/documentation/stable/0.26/locale/ja_JP/tutorials/circuits/3_summary_of_quantum_operations.html\n\n    # desired_vector = [\n    # 1 / math.sqrt(16) * complex(0, 1),\n    # 1 / math.sqrt(8) * complex(1, 0),\n    # 1 / math.sqrt(16) * complex(1, 1),\n    # 0,\n    # 0,\n    # 1 / math.sqrt(8) * complex(1, 2),\n    # 1 / math.sqrt(16) * complex(1, 0),\n    # 0]\n\n    desired_vector = [\n        1 / math.sqrt(3) * complex(1, 0),\n        1 / math.sqrt(3) * complex(1, 0),\n        1 / math.sqrt(3) * complex(1, 0),\n        0,\n    ]\n\n    q = QuantumRegister(2)\n    qc = QuantumCircuit(q)\n\n    qc.initialize(desired_vector, [q[0], q[1]])\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE5A48963AC3B", "submission_order": 2, "result": "WA", "execution_time": "840 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)  # Hadamard gate\n    qc.h(1)  # hadamard gate\n\n    qc.reset(1)  # reset 1\n\n    qc.rx(math.pi / 3, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE5A48963AC3B", "submission_order": 3, "result": "WA", "execution_time": "824 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.ry(2 * math.acos(1 / math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE5A48963AC3B", "submission_order": 4, "result": "AC", "execution_time": "927 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.ry(2 * math.acos(1 / math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE7730281F9F8", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    from qiskit.circuit.library.data_preparation import UniformSuperpositionGate\n    us = UniformSuperpositionGate(3,2)\n    qc.append(us,list(range(2)))\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE7730281F9F8", "submission_order": 2, "result": "WA", "execution_time": "1516 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    t = -2*math.acos(math.sqrt(1/3))\n    qc.x(0)\n    qc.x(1)\n    qc.ry(t,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AE7730281F9F8", "submission_order": 3, "result": "AC", "execution_time": "1577 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    t = -2*math.acos(math.sqrt(1/3))\n    qc.x(1)\n    qc.ry(t,1)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AEC2629245A8C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cp(-np.pi,0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AEC2629245A8C", "submission_order": 2, "result": "WA", "execution_time": "827 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\npi = 3.141592\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cp(-pi,0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AEC2629245A8C", "submission_order": 3, "result": "WA", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cp(-pi,0,1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECA3BC473E5E", "submission_order": 1, "result": "WA", "execution_time": "1068 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.cry(theta, 0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECA3BC473E5E", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef create_custom_gate():\n    U = np.array([[1/np.sqrt(3), 0, 0, 0],\n                  [1/np.sqrt(3), 0, 0, 0],\n                  [1/np.sqrt(3), 0, 0, 0],\n                  [0, 0, 0, 0]])\n\n    custom_gate = Operator(U)\n    return custom_gate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    custom_gate = create_custom_gate()\n    qc.unitary(custom_gate, [0, 1], label='Custom')\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECA3BC473E5E", "submission_order": 3, "result": "RE", "execution_time": "1000 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef create_custom_gate():\n    U = np.array([[1/math.sqrt(3), 0, 0, 0],\n                  [1/math.sqrt(3), 0, 0, 0],\n                  [1/math.sqrt(3), 0, 0, 0],\n                  [0, 0, 0, 0]])\n\n    custom_gate = Operator(U)\n    return custom_gate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    custom_gate = create_custom_gate()\n    qc.unitary(custom_gate, [0, 1], label='Custom')\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECA3BC473E5E", "submission_order": 4, "result": "RE", "execution_time": "904 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef create_custom_gate():\n    U = np.array([[1/math.sqrt(3), 1/math.sqrt(3), 1/math.sqrt(3), 0],\n                  [1/math.sqrt(3), 1/math.sqrt(2), -1/math.sqrt(6), -1/math.sqrt(2)],\n                  [1/math.sqrt(3), -1/math.sqrt(2), -1/math.sqrt(6), 1/math.sqrt(2)],\n                  [0, 0, math.sqrt(2)/math.sqrt(3), 0]])\n\n    custom_gate = Operator(U)\n    return custom_gate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    custom_gate = create_custom_gate()\n    qc.unitary(custom_gate, [0, 1], label='Custom')\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECA3BC473E5E", "submission_order": 5, "result": "RE", "execution_time": "809 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef create_custom_gate():\n\n    custom_gate = Operator([[1/math.sqrt(3), 1/math.sqrt(3), 1/math.sqrt(3), 0],\n                  [1/math.sqrt(3), 1/math.sqrt(2), -1/math.sqrt(6), -1/math.sqrt(2)],\n                  [1/math.sqrt(3), -1/math.sqrt(2), -1/math.sqrt(6), 1/math.sqrt(2)],\n                  [0, 0, math.sqrt()/math.sqrt(3), 0]])\n    return custom_gate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    custom_gate = create_custom_gate()\n    qc.unitary(custom_gate, [0, 1], label='Custom')\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECA3BC473E5E", "submission_order": 6, "result": "WA", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n\n    # 制御回転ゲートを適用\n    theta = 2 * acos(sqrt(2/3))\n    qc.cry(theta, 0, 1)\n\n    # CNOTゲートを適用\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECB31651CD01", "submission_order": 1, "result": "RE", "execution_time": "706 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    alpha = 1/3\n    qc.u1(alpha, 0)\n    qc.u1(alpha, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECB31651CD01", "submission_order": 2, "result": "RE", "execution_time": "1006 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    alpha = 1/3\n    qc.u1(alpha, 0)\n    qc.u1(2*alpha, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECB31651CD01", "submission_order": 3, "result": "WA", "execution_time": "851 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECB31651CD01", "submission_order": 4, "result": "RE", "execution_time": "804 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n    \n    angle = math.pi / 4\n    qc.u1(angle, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECB31651CD01", "submission_order": 5, "result": "WA", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    angle = math.pi / 4\n    qc.rx(angle, 0)\n    qc.ry(angle, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECB31651CD01", "submission_order": 6, "result": "WA", "execution_time": "882 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    angle = math.pi / 4\n    qc.rx(angle, 0)\n    qc.rx(angle, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECD4AAB7DF8F", "submission_order": 1, "result": "WA", "execution_time": "818 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Qubit 0を|0>と|1>の重ね合わせ状態にする（Hadamardゲート）\n    qc.h(0)\n\n    # Qubit 1を|0>の状態にする\n    # Qubit 0が|1>の場合のみ、Qubit 1を|1>にするための制御NOTゲートを適用\n    qc.cx(0, 1)\n\n    # Qubit 1の振幅を調整するための回転ゲート\n    qc.ry(2 * math.acos(1 / math.sqrt(3)), 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECD4AAB7DF8F", "submission_order": 2, "result": "WA", "execution_time": "814 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Qubit 0にHadamardゲートを適用\n    qc.h(0)\n\n    # Qubit 1にRYゲートを適用して、|0>と|1>の確率を調整\n    qc.ry(2 * math.acos(1 / math.sqrt(3)), 1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECD4AAB7DF8F", "submission_order": 3, "result": "WA", "execution_time": "859 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Qubit 0にHadamardゲートを適用\n    qc.h(0)\n\n    # Qubit 0が|1>の場合にのみQubit 1を反転させる制御NOTゲート\n    qc.cx(0, 1)\n\n    # Qubit 0が|0>の状態である場合にのみQubit 1を|0>から|1>へ回転させる\n    qc.x(0)  # Qubit 0を反転\n    qc.cry(2 * math.acos(1 / math.sqrt(3)), 0, 1)  # 制御回転Yゲート\n    qc.x(0)  # Qubit 0を元に戻す\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECD4AAB7DF8F", "submission_order": 4, "result": "WA", "execution_time": "837 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # theta0 と theta1 を計算\n    theta0 = 2 * acos(1 / sqrt(3))\n    theta1 = 2 * acos(1 / sqrt(2))\n\n    # 最初の量子ビットに RY ゲートを適用\n    qc.ry(theta0, 0)\n\n    # 2番目の量子ビットに条件付き RY ゲートを適用\n    qc.cry(theta1, 0, 1)\n\n    # 最後に、2番目の量子ビットにアダマールゲートを適用\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECD4AAB7DF8F", "submission_order": 5, "result": "WA", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply a rotation to the first qubit\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n\n    # Apply a controlled rotation to the second qubit\n    qc.cry(2 * math.acos(math.sqrt(2/3)), 0, 1)\n\n    # Apply a X gate to the second qubit to achieve the desired superposition\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AECD4AAB7DF8F", "submission_order": 6, "result": "AC", "execution_time": "901 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n\n# from qiskit import Aer, execute\n\n# simulator = Aer.get_backend('statevector_simulator')\n# result = execute(solve(), simulator).result()\n# statevector = result.get_statevector()\n# print(statevector)\n'''"}
{"problem": "QPC001_A5", "user": "AED78AD793BAB", "submission_order": 1, "result": "AC", "execution_time": "1288 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Solve[cos(x/2) = 1/sqrt(3) and sin(x/2) = sqrt(2/3), x]\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AEE25F7289941", "submission_order": 1, "result": "RE", "execution_time": "815 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AEE25F7289941", "submission_order": 2, "result": "AC", "execution_time": "918 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AEFF8868512EF", "submission_order": 1, "result": "RE", "execution_time": "1374 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AEFF8868512EF", "submission_order": 2, "result": "AC", "execution_time": "1395 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF08DFEFCA2F3", "submission_order": 1, "result": "AC", "execution_time": "972 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.asin(1.0/math.sqrt(3.0))\n    qc.ry(2.0 * theta,0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF09C050E5E2B", "submission_order": 1, "result": "WA", "execution_time": "1579 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF09C050E5E2B", "submission_order": 2, "result": "RE", "execution_time": "768 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=acos(sqrt(1/3))\n    qc.append(RYGate(t))\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF09C050E5E2B", "submission_order": 3, "result": "AC", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    t=math.acos(math.sqrt(1/3))\n    qc.append(RYGate(2*t),[1])\n    qc.ch(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF3687A0FA943", "submission_order": 1, "result": "RE", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.acos(math.sqrt(2)/math.sqrt(3)), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF3687A0FA943", "submission_order": 2, "result": "AC", "execution_time": "1420 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.acos(math.sqrt(2)/math.sqrt(3)), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF424CCEE67DC", "submission_order": 1, "result": "RE", "execution_time": "1221 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF424CCEE67DC", "submission_order": 2, "result": "WA", "execution_time": "1254 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF424CCEE67DC", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF424CCEE67DC", "submission_order": 4, "result": "AC", "execution_time": "1283 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AF70D3DC221EA", "submission_order": 1, "result": "AC", "execution_time": "1460 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta,0)\n\n    qc.ch(0,1)\n\n    qc.cx(1,0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFB6230BA8A69", "submission_order": 1, "result": "RE", "execution_time": "933 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = math.acos(math.sqrt(1 / 3)) * 2\n    qc.u(theta, 0, 0, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFB6230BA8A69", "submission_order": 2, "result": "AC", "execution_time": "860 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    theta = math.acos(math.sqrt(1 / 3)) * 2\n    qc.u(theta, 0, 0, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFB6728BCA381", "submission_order": 1, "result": "RE", "execution_time": "778 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    circ = qiskit.QuantumCircuit(2)\n    circ.ry(1.910633,0)\n    circ.ch(0,1)\n    circ.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFB6728BCA381", "submission_order": 2, "result": "RE", "execution_time": "839 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = qiskit.QuantumCircuit(2)\n    qc.ry(1.910633,0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFB6728BCA381", "submission_order": 3, "result": "RE", "execution_time": "741 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = qiskit.QuantumCircuit(2)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFB6728BCA381", "submission_order": 4, "result": "WA", "execution_time": "935 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFB6728BCA381", "submission_order": 5, "result": "AC", "execution_time": "799 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.910633,0)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFBF22B24B78F", "submission_order": 1, "result": "WA", "execution_time": "1381 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, sqrt, asin\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2 * asin(sqrt(2/3))\n    qc.cry(theta, 0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFBF22B24B78F", "submission_order": 2, "result": "WA", "execution_time": "1049 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, sqrt, asin\nfrom math import acos\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\n\ndef solve2(qc, n: int, L: int) -> QuantumCircuit:\n    M = L\n    # Write your code here:\n    ls = [i for i in range(n) if get_bit(M, i)]\n    if len(ls) == 0:\n        return qc\n    for l in ls:\n        qc.x(l)\n    l0 = ls[0]\n    if len(ls) == 1:\n        for i in range(l0):\n            qc.h(i)\n        return qc\n    l1 = ls[1]\n    M0 = 2 ** l0\n    if l0 > 0:\n        for i in range(l0):\n            qc.h(i)\n    theta0 = -2 * acos(sqrt(M0 / M))\n    qc.ry(theta0, l1)\n    qc.x(l1)\n    for i in range(l0, l1):\n        qc.ch(l1, i)\n    qc.x(l1)\n\n    k = len(ls) - 1\n\n    Mm = M0\n\n    for m in range(1, k):\n        theta_m = -2 * acos(sqrt(2 ** ls[m] / (M - Mm)))\n        qc.x(l[m])\n        qc.cry(theta_m, l[m+1], l[m])\n        qc.x(l[m])\n        qc.x(l[m+1])\n        for i in range(l[m], l[m+1]):\n            qc.ch(l[m+1], i)\n        qc.x(l[m+1])\n        Mm = Mm + 2 ** l[m]\n    \n    return qc\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    return solve2(qc, 2, 3)\n'''"}
{"problem": "QPC001_A5", "user": "AFBF22B24B78F", "submission_order": 3, "result": "AC", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\n\ndef solve2(qc, n: int, L: int) -> QuantumCircuit:\n    M = L\n    # Write your code here:\n    ls = [i for i in range(n) if get_bit(M, i)]\n    if len(ls) == 0:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    for l in ls[1:]:\n        qc.x(l)\n\n    l0 = ls[0]\n    if len(ls) == 1:\n        print(l0)\n        for i in range(l0):\n            qc.h(i)\n        return qc\n    \n    l1 = ls[1]\n    M0 = 2 ** l0\n    if l0 > 0:\n        for i in range(l0):\n            qc.h(i)\n    theta0 = -2 * acos(sqrt(M0 / M))\n    qc.ry(theta0, l1)\n\n    qc.x(l1)\n    for i in range(l0, l1):\n        qc.ch(l1, i)\n    qc.x(l1)\n\n    k = len(ls) - 1\n\n    Mm = M0\n\n    for m in range(1, k):\n        theta_m = -2 * acos(sqrt(2 ** ls[m] / (M - Mm)))\n        qc.x(ls[m])\n        qc.cry(theta_m, ls[m], ls[m+1])\n        qc.x(ls[m])\n        qc.x(ls[m+1])\n        for i in range(ls[m], ls[m+1]):\n            qc.ch(ls[m+1], i)\n        qc.x(ls[m+1])\n        Mm = Mm + 2 ** ls[m]\n    \n    return qc\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    return solve2(qc, 2, 3)\n'''"}
{"problem": "QPC001_A5", "user": "AFCDA305D1ED7", "submission_order": 1, "result": "WA", "execution_time": "888 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFCDA305D1ED7", "submission_order": 2, "result": "AC", "execution_time": "902 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    qc.ry(4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFD0CFC4E7FCD", "submission_order": 1, "result": "RE", "execution_time": "1062 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Apply the U gate on q0 with parameters (π/4, 0, 0)\n    qc.u(pi/4, 0, 0, 0)\n\n    # Apply the U gate on q1 with parameters (1.23, 0, 0)\n    qc.u(1.23, 0, 0, 1)\n\n    # Add a CX (CNOT) gate with q0 as control and q1 as target\n    qc.cx(1, 0)\n\n    # Apply another U gate on q0 with parameters (π/4, 0, 0)\n    qc.u(pi/4, 0, 0, 0)\n\n    # Add another CX gate with q0 as control and q1 as target\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFD0CFC4E7FCD", "submission_order": 2, "result": "WA", "execution_time": "1113 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Apply the U gate on q0 with parameters (π/4, 0, 0)\n    qc.u(pi/4, 0, 0, 0)\n\n    # Apply the U gate on q1 with parameters (1.23, 0, 0)\n    qc.u(1.23, 0, 0, 1)\n\n    # Add a CX (CNOT) gate with q0 as control and q1 as target\n    qc.cx(1, 0)\n\n    # Apply another U gate on q0 with parameters (π/4, 0, 0)\n    qc.u(pi/4, 0, 0, 0)\n\n    # Add another CX gate with q0 as control and q1 as target\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFD0CFC4E7FCD", "submission_order": 3, "result": "WA", "execution_time": "1131 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Apply the U gate on q0 with parameters (π/4, 0, 0)\n    qc.u(pi/4, 0, 0, 0)\n\n    # Apply the U gate on q1 with parameters (1.23, 0, 0)\n    qc.u(1.23, 0, 0, 1)\n\n    # Add a CX (CNOT) gate with q0 as control and q1 as target\n    qc.cx(1, 0)\n\n    # Apply another U gate on q0 with parameters (π/4, 0, 0)\n    qc.u(pi/4, 0, 0, 0)\n\n    # Add another CX gate with q0 as control and q1 as target\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFD0CFC4E7FCD", "submission_order": 4, "result": "WA", "execution_time": "1730 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Apply the U gate on q0 with parameters (π/4, 0, 0)\n    qc.u(pi/4, 0, 0, 0)\n\n    # Apply the U gate on q1 with parameters (1.23, 0, 0)\n    qc.u(1.23, 0, 0, 1)\n\n    # Add a CX (CNOT) gate with q0 as control and q1 as target\n    qc.cx(1, 0)\n\n    # Apply another U gate on q0 with parameters (π/4, 0, 0)\n    qc.u(pi/4, 0, 0, 0)\n\n    # Add another CX gate with q0 as control and q1 as target\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFEDA0C26C5A1", "submission_order": 1, "result": "WA", "execution_time": "835 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n# CXゲートを使用してエンタングルメントを作成\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFEDA0C26C5A1", "submission_order": 2, "result": "WA", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n\n# CNOTゲートを適用\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFEDA0C26C5A1", "submission_order": 3, "result": "AC", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC001_A5", "user": "AFFF057ADB4D3", "submission_order": 1, "result": "WA", "execution_time": "1449 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n\n    qc.s(0).inverse()\n\n    # CXゲートを1番目の量子ビットを制御ビット、2番目の量子ビットをターゲットビットに適用\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0037D0A7D49C", "submission_order": 1, "result": "AC", "execution_time": "1477 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0039AF0AB07D", "submission_order": 1, "result": "AC", "execution_time": "1643 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0079C6F84498", "submission_order": 1, "result": "AC", "execution_time": "1754 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    # CNOT\n    if x.size == 0:\n        pass\n    elif x.size == 1:\n        qc.cx(x, y)\n\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(qc)\n'''"}
{"problem": "QPC001_B1", "user": "A0089F40AEEDF", "submission_order": 1, "result": "AC", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 1, "result": "RE", "execution_time": "786 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 2, "result": "RE", "execution_time": "854 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 3, "result": "WA", "execution_time": "940 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 4, "result": "RE", "execution_time": "778 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cz(x[0], x[1])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 5, "result": "WA", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 6, "result": "WA", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 7, "result": "RE", "execution_time": "848 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(1, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 8, "result": "WA", "execution_time": "865 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 9, "result": "WA", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 10, "result": "WA", "execution_time": "897 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0^1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 11, "result": "RE", "execution_time": "742 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.o(0)\n    qc.o(1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 12, "result": "WA", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 13, "result": "WA", "execution_time": "904 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(0, 1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 14, "result": "WA", "execution_time": "825 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.cz(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 15, "result": "RE", "execution_time": "1113 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(2)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 16, "result": "RE", "execution_time": "767 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 17, "result": "WA", "execution_time": "999 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 18, "result": "WA", "execution_time": "1161 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 19, "result": "WA", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 20, "result": "WA", "execution_time": "828 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x)\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 21, "result": "WA", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.h(y)\n    qc.cx(x[0],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 22, "result": "WA", "execution_time": "977 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x)\n    qc.x(y)\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 23, "result": "WA", "execution_time": "980 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A01D75C81D8EA", "submission_order": 24, "result": "WA", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A020627DAD1BA", "submission_order": 1, "result": "AC", "execution_time": "1139 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A02119B0C6F55", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A02B98990FEF3", "submission_order": 1, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A03175E0E97CA", "submission_order": 1, "result": "AC", "execution_time": "896 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A04FDE830A37C", "submission_order": 1, "result": "AC", "execution_time": "1285 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A06FC92066AFE", "submission_order": 1, "result": "AC", "execution_time": "1326 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A07178481CB9E", "submission_order": 1, "result": "AC", "execution_time": "1623 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A07FB8FDCBADB", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0B1501B82463", "submission_order": 1, "result": "WA", "execution_time": "869 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit import (BasicAer,execute)\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0B1501B82463", "submission_order": 2, "result": "AC", "execution_time": "945 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit import (BasicAer,execute)\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0BE01E0FA692", "submission_order": 1, "result": "WA", "execution_time": "880 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(y, x)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0BE01E0FA692", "submission_order": 2, "result": "AC", "execution_time": "1043 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0, 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0C625050D1E6", "submission_order": 1, "result": "AC", "execution_time": "1726 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0DA89765CBA0", "submission_order": 1, "result": "AC", "execution_time": "1298 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0E7626793D1D", "submission_order": 1, "result": "AC", "execution_time": "1761 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0E924717167D", "submission_order": 1, "result": "WA", "execution_time": "1438 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0E924717167D", "submission_order": 2, "result": "AC", "execution_time": "1566 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0EE66967F198", "submission_order": 1, "result": "AC", "execution_time": "2078 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0F5F6C5D2B3A", "submission_order": 1, "result": "AC", "execution_time": "1491 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A0F890F1EA192", "submission_order": 1, "result": "AC", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A11663F96AB13", "submission_order": 1, "result": "AC", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A11B62A0FB380", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A12626C397D61", "submission_order": 1, "result": "AC", "execution_time": "1953 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x[0],y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A126FE39AB71B", "submission_order": 1, "result": "AC", "execution_time": "1157 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 1, "result": "WA", "execution_time": "929 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 2, "result": "WA", "execution_time": "842 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    qc.cx(y,x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 3, "result": "WA", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(y,x)\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 4, "result": "WA", "execution_time": "1095 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 5, "result": "WA", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(x,y)\n    qc.h(x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 6, "result": "WA", "execution_time": "855 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(x,y)\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 7, "result": "WA", "execution_time": "1065 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cz(y,x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 8, "result": "WA", "execution_time": "890 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cz(y,x)\n    qc.z(x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 9, "result": "WA", "execution_time": "909 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cz(y,x)\n    qc.x(x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 10, "result": "WA", "execution_time": "868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.x(x)\n    qc.cz(y,x)\n    qc.x(x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 11, "result": "WA", "execution_time": "988 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.x(x)\n    qc.h(y)\n    qc.cz(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 12, "result": "WA", "execution_time": "962 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.x(y)\n    qc.h(x)\n    qc.cz(y,x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 13, "result": "WA", "execution_time": "993 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(y,x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A13D30787D7E6", "submission_order": 14, "result": "AC", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A14249C56891B", "submission_order": 1, "result": "RE", "execution_time": "1659 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A14249C56891B", "submission_order": 2, "result": "RE", "execution_time": "1579 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A14249C56891B", "submission_order": 3, "result": "AC", "execution_time": "1838 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A14347E3E4128", "submission_order": 1, "result": "AC", "execution_time": "1150 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A15DE945C4505", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A162637224CDD", "submission_order": 1, "result": "AC", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A17EBB75747C9", "submission_order": 1, "result": "AC", "execution_time": "1710 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n \n    qc.cnot(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A183614C324B0", "submission_order": 1, "result": "AC", "execution_time": "1311 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.cx(x,y)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A185D26AAD95C", "submission_order": 1, "result": "AC", "execution_time": "886 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1966C7301A83", "submission_order": 1, "result": "AC", "execution_time": "1550 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1979EEAE415D", "submission_order": 1, "result": "AC", "execution_time": "1840 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A198E7C6D1D7E", "submission_order": 1, "result": "RE", "execution_time": "757 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A198E7C6D1D7E", "submission_order": 2, "result": "RE", "execution_time": "794 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A198E7C6D1D7E", "submission_order": 3, "result": "RE", "execution_time": "780 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A198E7C6D1D7E", "submission_order": 4, "result": "WA", "execution_time": "979 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.ch(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A198E7C6D1D7E", "submission_order": 5, "result": "WA", "execution_time": "871 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.ch(y, x)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A198E7C6D1D7E", "submission_order": 6, "result": "WA", "execution_time": "954 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.ch(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A198E7C6D1D7E", "submission_order": 7, "result": "AC", "execution_time": "1770 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A19FFAB62FED2", "submission_order": 1, "result": "WA", "execution_time": "1274 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A19FFAB62FED2", "submission_order": 2, "result": "WA", "execution_time": "1349 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A19FFAB62FED2", "submission_order": 3, "result": "AC", "execution_time": "1416 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1A12B8E0686E", "submission_order": 1, "result": "AC", "execution_time": "1800 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1A72AA7F0804", "submission_order": 1, "result": "WA", "execution_time": "1031 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1A72AA7F0804", "submission_order": 2, "result": "WA", "execution_time": "1177 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1A72AA7F0804", "submission_order": 3, "result": "AC", "execution_time": "1168 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1AD71CBF1BA0", "submission_order": 1, "result": "AC", "execution_time": "1959 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1C80A55D56AA", "submission_order": 1, "result": "AC", "execution_time": "1409 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1DF281C5F97A", "submission_order": 1, "result": "AC", "execution_time": "970 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A1FAFA034CC10", "submission_order": 1, "result": "AC", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A20DC10134BDA", "submission_order": 1, "result": "AC", "execution_time": "1702 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A21D810D398C0", "submission_order": 1, "result": "WA", "execution_time": "847 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y[0])  \n    qc.cx(y[0],x[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A21D810D398C0", "submission_order": 2, "result": "AC", "execution_time": "888 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x[0],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A21EBBD4562AA", "submission_order": 1, "result": "WA", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A21EBBD4562AA", "submission_order": 2, "result": "AC", "execution_time": "847 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A22B83B2AFB3F", "submission_order": 1, "result": "AC", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A22E6D019E7B7", "submission_order": 1, "result": "RE", "execution_time": "1819 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A22E6D019E7B7", "submission_order": 2, "result": "AC", "execution_time": "2380 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A231CF2E2F6AF", "submission_order": 1, "result": "RE", "execution_time": "745 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    # 0が0→そのまま, 0が1→反転\n    qc.cz(x[0],x[1])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A231CF2E2F6AF", "submission_order": 2, "result": "RE", "execution_time": "759 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    # 0が0→そのまま, 0が1→反転\n    qc.cz(x[0],y[1])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A231CF2E2F6AF", "submission_order": 3, "result": "WA", "execution_time": "1111 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # 0が0→そのまま, 0が1→反転\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A231CF2E2F6AF", "submission_order": 4, "result": "WA", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # 0が0→そのまま, 0が1→反転\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A231CF2E2F6AF", "submission_order": 5, "result": "WA", "execution_time": "870 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # 0が0→そのまま, 0が1→反転\n    qc.h(0)\n    qc.h(1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A231CF2E2F6AF", "submission_order": 6, "result": "AC", "execution_time": "1802 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # xが0, yが1の2量子ビット回路とみなす\n    # 0ビット目はそのまま，1ビット目を入力0ビットと1ビットの排他的論理和を取る\n    # つまり．|00> => |00>, |01> => |11>, |10> => |10>, |11> => |01>\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A23423E6A8CD1", "submission_order": 1, "result": "AC", "execution_time": "925 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 1, "result": "RE", "execution_time": "1407 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    def oracle(qci,x,y_fx):\n        qci.cx(x,y_fx)\n        qci.x(y_fx)\n    qc.x(1)\n    for i range(2):\n        qc.h([i])\n    oracle(qc,0,1)\n    for i in range(2):\n        qc.h([i])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 2, "result": "RE", "execution_time": "763 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    def oracle(qci,x,y_fx):\n        qci.cx(x,y_fx)\n        qci.x(y_fx)\n        qc.x(1)\n    for i range(2):\n        qc.h([i])\n    oracle(qc,0,1)\n    for i in range(2):\n        qc.h([])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 3, "result": "RE", "execution_time": "780 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    for i in range(2):       qc.h([i])\n    qc.cz(0,1)\n    for i in range(2):       qc.h([i])\n    for i in range(2):       qc.x([i])\n    qc.cz(0,1)\n    for i in range(2):       qc.x([i])\n    for i in range(2):       qc.h([i])\n    return rc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 4, "result": "WA", "execution_time": "867 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    def c_oracle(qci,x,y_fx):\n        qci.x(y_fx)\n    qc.x(1)\n    for i in range(2):\n        qc.h([i])\n    c_oracle(qc,0,1)\n    for i in range(2):\n        qc.h([i])\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 5, "result": "RE", "execution_time": "783 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n   def dj_oracle(qci,x0,f_x):\n    qci.cx(x0,f_x)\n    qc.x(2)\n    for i in range(2):\n        qc.h([i])\n    dj_oracle(qc,0,1)\n    for i in range(2):\n        qc.h([i])\n\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 6, "result": "RE", "execution_time": "762 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    oracle = LogicalExpressionOracle(expression)\n    qc.oracle\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 7, "result": "RE", "execution_time": "750 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\ndef bv_oracle(qci,x0,f_x)\n    qci.cx(x0,f_x)\n    qc.x([1])\n    for i in range(2):\n        qc.h([i])\n    for i in range(2):\n        qc.h([i])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 8, "result": "RE", "execution_time": "797 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\ndef oracle(qc):\n    # 例として、00の状態に対して位相を反転するオラクルを実装\n    qc.cz(0, 1)  # 00の状態に対してCZゲートを適用\n    \n    oracle(qc)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 9, "result": "RE", "execution_time": "868 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\ndef oracle(qc):\n    # 例として、00の状態に対して位相を反転するオラクルを実装\n    qc.cz(0, 1)  # 00の状態に対してCZゲートを適用\n    \n    oracle(qc)\n\nreturn qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 10, "result": "WA", "execution_time": "920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.cz(0, 1)  # 00の状態に対してCZゲートを適用\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26C45761552D", "submission_order": 11, "result": "AC", "execution_time": "903 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.cz(0, 1)  # 00の状態に対してCZゲートを適用\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A26F276D71D32", "submission_order": 1, "result": "AC", "execution_time": "1797 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A27B78FE15F4D", "submission_order": 1, "result": "AC", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    # CNOTゲートを使用して制御ビットと対象ビットのXORを実行\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A27D5ED90A6A9", "submission_order": 1, "result": "WA", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.h(0)\n    qc.h(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A27D5ED90A6A9", "submission_order": 2, "result": "WA", "execution_time": "884 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.ch(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A27D5ED90A6A9", "submission_order": 3, "result": "AC", "execution_time": "918 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A28BF0A2F2A7F", "submission_order": 1, "result": "AC", "execution_time": "1617 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A28D8E0091044", "submission_order": 1, "result": "AC", "execution_time": "1086 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A2A89F813D01D", "submission_order": 1, "result": "AC", "execution_time": "950 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A2CEFD84FDB89", "submission_order": 1, "result": "AC", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A2D3363BCEB94", "submission_order": 1, "result": "AC", "execution_time": "1705 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A2DF227402DEE", "submission_order": 1, "result": "AC", "execution_time": "1426 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A2DF9D88A50F8", "submission_order": 1, "result": "AC", "execution_time": "1379 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A2E969B77532D", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A2F1DC8F6C04C", "submission_order": 1, "result": "AC", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A2FC79CA4636D", "submission_order": 1, "result": "AC", "execution_time": "1418 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A309716BCADAB", "submission_order": 1, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x[0],y[0])\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A30E54A91DC52", "submission_order": 1, "result": "AC", "execution_time": "1580 ms", "memory": "143 MiB", "code": "'''python\n# \\lvert x \\rangle \\lvert y \\rangle \\xrightarrow{O} \\lvert x \\rangle \\lvert y \\oplus x \\rangle\n\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A32DAE51276F1", "submission_order": 1, "result": "AC", "execution_time": "1715 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A348BF4F34E3A", "submission_order": 1, "result": "WA", "execution_time": "2040 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A348BF4F34E3A", "submission_order": 2, "result": "WA", "execution_time": "1862 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A348BF4F34E3A", "submission_order": 3, "result": "WA", "execution_time": "1972 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cz(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A348BF4F34E3A", "submission_order": 4, "result": "WA", "execution_time": "1960 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cz(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A348BF4F34E3A", "submission_order": 5, "result": "WA", "execution_time": "1896 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A348BF4F34E3A", "submission_order": 6, "result": "RE", "execution_time": "1861 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.c(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A348BF4F34E3A", "submission_order": 7, "result": "AC", "execution_time": "1828 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A35E4028ADEB2", "submission_order": 1, "result": "AC", "execution_time": "1504 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A37E35A3F7798", "submission_order": 1, "result": "RE", "execution_time": "828 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    x, y = QuantumRegister(1), QuantumRegister(1)\n\n    qc.cnot(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A37E35A3F7798", "submission_order": 2, "result": "AC", "execution_time": "950 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    \n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A38BC93243821", "submission_order": 1, "result": "AC", "execution_time": "1185 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A3B13A8E353F8", "submission_order": 1, "result": "RE", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A3B13A8E353F8", "submission_order": 2, "result": "AC", "execution_time": "1371 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A3C8555B2C9E4", "submission_order": 1, "result": "AC", "execution_time": "1360 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\n#from qiskit.quantum_info import Statevector\nimport numpy as np\n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n \n    return qc\n \nqc = solve()\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC001_B1", "user": "A3E15DB796D71", "submission_order": 1, "result": "WA", "execution_time": "1753 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A3E15DB796D71", "submission_order": 2, "result": "AC", "execution_time": "1497 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A3E7416743B39", "submission_order": 1, "result": "AC", "execution_time": "2446 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A3FAC15DAEFB2", "submission_order": 1, "result": "AC", "execution_time": "926 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A438D1D812A09", "submission_order": 1, "result": "AC", "execution_time": "1476 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A451CC40EC9A2", "submission_order": 1, "result": "AC", "execution_time": "977 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A455E37DFF323", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A45602048DB99", "submission_order": 1, "result": "AC", "execution_time": "2006 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A46A5C7A0EFA1", "submission_order": 1, "result": "AC", "execution_time": "1995 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A47117F8D8DDA", "submission_order": 1, "result": "AC", "execution_time": "1874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)  \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4768A441AE3F", "submission_order": 1, "result": "QLE", "execution_time": "831 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(2), QuantumRegister(2)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0],y[0])\n    qc.cx(x[0],y[1])\n    qc.cx(x[1],y[0])\n    qc.cx(x[1],y[1])\n    qc.x(y[0])\n    qc.x(y[1])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4768A441AE3F", "submission_order": 2, "result": "AC", "execution_time": "1397 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0],y[0])\n\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A47D3FB4AB514", "submission_order": 1, "result": "AC", "execution_time": "1067 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x,y)    \n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A485907273351", "submission_order": 1, "result": "WA", "execution_time": "1716 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A485907273351", "submission_order": 2, "result": "AC", "execution_time": "1720 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A491C414E32C5", "submission_order": 1, "result": "AC", "execution_time": "1539 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4979381BB6FF", "submission_order": 1, "result": "AC", "execution_time": "1323 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A499140C5DE79", "submission_order": 1, "result": "WA", "execution_time": "1892 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cs(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A499140C5DE79", "submission_order": 2, "result": "AC", "execution_time": "2049 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4BD6ED1870D5", "submission_order": 1, "result": "AC", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4CBD9F3C02D1", "submission_order": 1, "result": "AC", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4CEBF032C247", "submission_order": 1, "result": "AC", "execution_time": "998 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4DADD79CE021", "submission_order": 1, "result": "AC", "execution_time": "985 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4E3EC02A79D7", "submission_order": 1, "result": "AC", "execution_time": "919 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4FB0C22CD203", "submission_order": 1, "result": "AC", "execution_time": "1143 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A4FDB92605DD9", "submission_order": 1, "result": "AC", "execution_time": "2021 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A501ACBF9F540", "submission_order": 1, "result": "AC", "execution_time": "1619 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A50FD9A1F7957", "submission_order": 1, "result": "AC", "execution_time": "1437 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5137277A7A21", "submission_order": 1, "result": "AC", "execution_time": "2028 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A517428F4604E", "submission_order": 1, "result": "AC", "execution_time": "868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A52815E9E14F2", "submission_order": 1, "result": "AC", "execution_time": "885 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 1, "result": "WA", "execution_time": "1025 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 2, "result": "RE", "execution_time": "865 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(1, x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 3, "result": "RE", "execution_time": "784 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x, y, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 4, "result": "WA", "execution_time": "974 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(y, x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 5, "result": "WA", "execution_time": "941 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(y, x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 6, "result": "WA", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 7, "result": "WA", "execution_time": "915 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 8, "result": "WA", "execution_time": "994 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here: \n    qc.h(0)   \n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 9, "result": "WA", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here: \n    qc.h(0)   \n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 10, "result": "WA", "execution_time": "903 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here: \n    qc.h(0)   \n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 11, "result": "WA", "execution_time": "876 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here: \n    qc.h(0)   \n    qc.cnot(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 12, "result": "WA", "execution_time": "939 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here: \n    qc.h(0)   \n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 13, "result": "WA", "execution_time": "879 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here: \n    qc.h(0)   \n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A530FAC21708A", "submission_order": 14, "result": "WA", "execution_time": "859 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here: \n    qc.h(0)   \n    qc.cx(y,x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5336AE2ADB4F", "submission_order": 1, "result": "AC", "execution_time": "912 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A547B5831B157", "submission_order": 1, "result": "AC", "execution_time": "887 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A54A0AD17A0B6", "submission_order": 1, "result": "WA", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A54A0AD17A0B6", "submission_order": 2, "result": "AC", "execution_time": "851 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A56895ED0497B", "submission_order": 1, "result": "AC", "execution_time": "2117 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A56AF638A3386", "submission_order": 1, "result": "AC", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5708BBC1EA0A", "submission_order": 1, "result": "AC", "execution_time": "1542 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A57BCEFCC49C8", "submission_order": 1, "result": "AC", "execution_time": "962 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5944F5A2206F", "submission_order": 1, "result": "AC", "execution_time": "2123 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Apply a CNOT gate \n    qc.cx(x[0], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A59F2FC6DE17F", "submission_order": 1, "result": "AC", "execution_time": "1925 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5B0BED712376", "submission_order": 1, "result": "RE", "execution_time": "774 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5B0BED712376", "submission_order": 2, "result": "RE", "execution_time": "879 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5B0BED712376", "submission_order": 3, "result": "AC", "execution_time": "1752 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5B3B83F8D677", "submission_order": 1, "result": "AC", "execution_time": "1624 ms", "memory": "162 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5B4DAD1A2F79", "submission_order": 1, "result": "AC", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5CF48869F3F2", "submission_order": 1, "result": "AC", "execution_time": "1401 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5DAC466C1D52", "submission_order": 1, "result": "AC", "execution_time": "916 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x[0],y[0])\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5E844B8079F0", "submission_order": 1, "result": "AC", "execution_time": "1883 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5F55E8028E9C", "submission_order": 1, "result": "WA", "execution_time": "1008 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.h(y)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5F55E8028E9C", "submission_order": 2, "result": "WA", "execution_time": "1277 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.h(1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A5F55E8028E9C", "submission_order": 3, "result": "AC", "execution_time": "1428 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A60FF86700613", "submission_order": 1, "result": "AC", "execution_time": "1274 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.cx(x, y)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6128CEB7D0B8", "submission_order": 1, "result": "RE", "execution_time": "776 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6128CEB7D0B8", "submission_order": 2, "result": "AC", "execution_time": "977 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A655250EF7876", "submission_order": 1, "result": "AC", "execution_time": "1599 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6562FCF6C940", "submission_order": 1, "result": "AC", "execution_time": "1034 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6712DB32CDD2", "submission_order": 1, "result": "AC", "execution_time": "1408 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A673C13ACF46C", "submission_order": 1, "result": "AC", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x, y)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6793C8C8A962", "submission_order": 1, "result": "AC", "execution_time": "826 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A688FD7446CB0", "submission_order": 1, "result": "AC", "execution_time": "1419 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A695336DF0192", "submission_order": 1, "result": "AC", "execution_time": "1589 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A699DB2301E19", "submission_order": 1, "result": "AC", "execution_time": "1192 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A69D953D13BA2", "submission_order": 1, "result": "AC", "execution_time": "919 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6A497231D558", "submission_order": 1, "result": "RE", "execution_time": "692 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.xor(2,x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6A497231D558", "submission_order": 2, "result": "RE", "execution_time": "718 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.xor(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6A497231D558", "submission_order": 3, "result": "AC", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6D4ED69F395D", "submission_order": 1, "result": "AC", "execution_time": "966 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6D8C7E89F67B", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6DEAB577506E", "submission_order": 1, "result": "AC", "execution_time": "1894 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A6EE847040088", "submission_order": 1, "result": "AC", "execution_time": "1585 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A72977A667492", "submission_order": 1, "result": "AC", "execution_time": "1583 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A73FB9B78E1C9", "submission_order": 1, "result": "AC", "execution_time": "752 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A752A78B85D2E", "submission_order": 1, "result": "AC", "execution_time": "2102 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A75D4FA5D2F29", "submission_order": 1, "result": "AC", "execution_time": "1674 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A77A55648C5F3", "submission_order": 1, "result": "WA", "execution_time": "1547 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A77A55648C5F3", "submission_order": 2, "result": "AC", "execution_time": "1622 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A785355D903A9", "submission_order": 1, "result": "AC", "execution_time": "1558 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A78828FF555D0", "submission_order": 1, "result": "AC", "execution_time": "985 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A79104DE3F64C", "submission_order": 1, "result": "AC", "execution_time": "885 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A792E46C78702", "submission_order": 1, "result": "RE", "execution_time": "1346 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(x)\n    qc.x(y)\n    qc.cnot(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A792E46C78702", "submission_order": 2, "result": "RE", "execution_time": "1090 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(x)\n    qc.cnot(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A792E46C78702", "submission_order": 3, "result": "RE", "execution_time": "1099 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cnot(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A792E46C78702", "submission_order": 4, "result": "RE", "execution_time": "1357 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cnot(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A792E46C78702", "submission_order": 5, "result": "AC", "execution_time": "1334 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A797455F11025", "submission_order": 1, "result": "AC", "execution_time": "1609 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A79FAD46D022A", "submission_order": 1, "result": "AC", "execution_time": "1690 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A7A0F79FD26AF", "submission_order": 1, "result": "AC", "execution_time": "1350 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A7A800D0135C4", "submission_order": 1, "result": "WA", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(y, x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A7A800D0135C4", "submission_order": 2, "result": "AC", "execution_time": "1007 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A7C20ABA56C46", "submission_order": 1, "result": "AC", "execution_time": "1517 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A7E809EBE4775", "submission_order": 1, "result": "AC", "execution_time": "1887 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A7F79EC83247A", "submission_order": 1, "result": "AC", "execution_time": "1763 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A7F980F010CD5", "submission_order": 1, "result": "AC", "execution_time": "1614 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Apply CNOT gate to implement the oracle\n    qc.cx(x, y)\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8005CC8EEFF0", "submission_order": 1, "result": "AC", "execution_time": "1368 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A807270BB57DF", "submission_order": 1, "result": "AC", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8486C3B53368", "submission_order": 1, "result": "AC", "execution_time": "889 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A85D4435A4A78", "submission_order": 1, "result": "AC", "execution_time": "2861 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x,y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A87C066C0A13E", "submission_order": 1, "result": "AC", "execution_time": "1930 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    qc.cnot(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A87E6D4075812", "submission_order": 1, "result": "AC", "execution_time": "994 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8993BD8A88B6", "submission_order": 1, "result": "AC", "execution_time": "1534 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8C4F98D8B33A", "submission_order": 1, "result": "AC", "execution_time": "1609 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8C6F1F0E3387", "submission_order": 1, "result": "AC", "execution_time": "1183 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8C8DFB009969", "submission_order": 1, "result": "AC", "execution_time": "1909 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.cx(x[0], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8D07FBD0A9D1", "submission_order": 1, "result": "AC", "execution_time": "928 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n\tx, y = QuantumRegister(1), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tqc.cx(0, 1)\n\treturn qc\n'''"}
{"problem": "QPC001_B1", "user": "A8D583946EB90", "submission_order": 1, "result": "AC", "execution_time": "1116 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8E3C3CC66AAA", "submission_order": 1, "result": "AC", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\ndef solve() -> QuantumCircuit:\n  x, y = QuantumRegister(1), QuantumRegister(1)\n  qc = QuantumCircuit(x, y)\n  qc.cx(0, 1)\n  return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8E53213C8BCF", "submission_order": 1, "result": "AC", "execution_time": "1731 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8EC115FF65A8", "submission_order": 1, "result": "AC", "execution_time": "864 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8EF65063BCA5", "submission_order": 1, "result": "AC", "execution_time": "908 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8F1D2720926B", "submission_order": 1, "result": "RE", "execution_time": "775 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.o(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A8F1D2720926B", "submission_order": 2, "result": "RE", "execution_time": "886 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.u(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9137D7A66F28", "submission_order": 1, "result": "AC", "execution_time": "1001 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9191F96A252F", "submission_order": 1, "result": "AC", "execution_time": "1044 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A91A9D6B96FD7", "submission_order": 1, "result": "AC", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A91B6AD469977", "submission_order": 1, "result": "AC", "execution_time": "2197 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A922608687F19", "submission_order": 1, "result": "AC", "execution_time": "1000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A92D6DA26C616", "submission_order": 1, "result": "AC", "execution_time": "1648 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A952FA1EF3C0F", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\nfrom qiskit import transpile\nfrom qiskit.circuit.library import RealAmplitudes\nfrom qiskit.quantum_info import SparsePauliOp\nfrom qiskit_aer import AerSimulator\nfrom qiskit import QuantumCircuit\nfrom qiskit.visualization import plot_histogram, plot_state_city\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    circ = QuantumCircuit(x, y)\n    # Write your code here:\n\n    circ = QuantumCircuit(2)\n    circ.cx(0, 1)\n    return circ\n'''"}
{"problem": "QPC001_B1", "user": "A952FA1EF3C0F", "submission_order": 2, "result": "AC", "execution_time": "1582 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    circ = QuantumCircuit(x, y)\n    # Write your code here:\n\n    circ = QuantumCircuit(2)\n    circ.cx(0, 1)\n    return circ\n'''"}
{"problem": "QPC001_B1", "user": "A98068A34E098", "submission_order": 1, "result": "AC", "execution_time": "2041 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9864E3ED86B4", "submission_order": 1, "result": "AC", "execution_time": "901 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A98EE8A80B837", "submission_order": 1, "result": "AC", "execution_time": "1529 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9987D2A332E9", "submission_order": 1, "result": "AC", "execution_time": "1013 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y);\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A99B2C2CDFADD", "submission_order": 1, "result": "AC", "execution_time": "1340 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9A45D647E45F", "submission_order": 1, "result": "WA", "execution_time": "1137 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9A45D647E45F", "submission_order": 2, "result": "WA", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9A45D647E45F", "submission_order": 3, "result": "AC", "execution_time": "1720 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 1, "result": "WA", "execution_time": "894 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 2, "result": "WA", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 3, "result": "WA", "execution_time": "1056 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 4, "result": "RE", "execution_time": "752 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n   qc.h(x[0])\n\n    # CXゲートを使用してエンタングルメントを作成\n    qc.cx(x[0], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 5, "result": "RE", "execution_time": "737 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n   qc.h(x)\n\n    # CXゲートを使用してエンタングルメントを作成\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 6, "result": "WA", "execution_time": "828 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x[0])\n\n    # CXゲートを使用してエンタングルメントを作成\n    qc.cx(x[0], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 7, "result": "WA", "execution_time": "1103 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x[0])\n\n    # CXゲートを使用してエンタングルメントを作成\n    qc.cx(x[0], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 8, "result": "WA", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    # Hadamardゲートを適用して重ね合わせ状態を生成\n    qc.h(x[0])\n\n    # CXゲートを使用してエンタングルメントを作成\n    qc.cx(x[0], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C18195D8F6D", "submission_order": 9, "result": "AC", "execution_time": "1204 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C38B6D4A613", "submission_order": 1, "result": "RE", "execution_time": "749 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x^y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C38B6D4A613", "submission_order": 2, "result": "RE", "execution_time": "829 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    y ^= x\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C38B6D4A613", "submission_order": 3, "result": "WA", "execution_time": "908 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C38B6D4A613", "submission_order": 4, "result": "RE", "execution_time": "1153 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.toffoli(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C38B6D4A613", "submission_order": 5, "result": "RE", "execution_time": "742 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.ccx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C38B6D4A613", "submission_order": 6, "result": "RE", "execution_time": "821 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.ccx(0, 1, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C38B6D4A613", "submission_order": 7, "result": "RE", "execution_time": "766 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.ccx(x[0], y[0], qc[1])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9C38B6D4A613", "submission_order": 8, "result": "AC", "execution_time": "1873 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9CAC209B045F", "submission_order": 1, "result": "AC", "execution_time": "1475 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9E58E2F05D60", "submission_order": 1, "result": "AC", "execution_time": "1420 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9E793A6B53FC", "submission_order": 1, "result": "AC", "execution_time": "1292 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "A9F2C931E8194", "submission_order": 1, "result": "AC", "execution_time": "898 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA00F37FF91DE", "submission_order": 1, "result": "AC", "execution_time": "1328 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA06425B5A16C", "submission_order": 1, "result": "AC", "execution_time": "1910 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA0793C60C734", "submission_order": 1, "result": "AC", "execution_time": "1033 ms", "memory": "90 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA16CCB79F8AB", "submission_order": 1, "result": "AC", "execution_time": "1830 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA1A0915AF6D3", "submission_order": 1, "result": "AC", "execution_time": "1517 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA2391877C7E6", "submission_order": 1, "result": "WA", "execution_time": "828 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA2391877C7E6", "submission_order": 2, "result": "WA", "execution_time": "866 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA2391877C7E6", "submission_order": 3, "result": "WA", "execution_time": "922 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    qc.cx(y,x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA2391877C7E6", "submission_order": 4, "result": "WA", "execution_time": "1149 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(y,x)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA2391877C7E6", "submission_order": 5, "result": "AC", "execution_time": "1951 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA3897504591E", "submission_order": 1, "result": "AC", "execution_time": "1433 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA3B37B468A51", "submission_order": 1, "result": "WA", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    oracle = \"i\"\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA3B37B468A51", "submission_order": 2, "result": "AC", "execution_time": "1328 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA5CF8B163CB4", "submission_order": 1, "result": "AC", "execution_time": "908 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA5DD45121CCE", "submission_order": 1, "result": "AC", "execution_time": "805 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA69F48ED02E2", "submission_order": 1, "result": "AC", "execution_time": "1480 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA838502F9197", "submission_order": 1, "result": "AC", "execution_time": "995 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA88C4505F91C", "submission_order": 1, "result": "AC", "execution_time": "1251 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA9861599A920", "submission_order": 1, "result": "AC", "execution_time": "981 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA9BC052D82B8", "submission_order": 1, "result": "AC", "execution_time": "1965 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AA9E0BB7DFFEB", "submission_order": 1, "result": "AC", "execution_time": "932 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AAA721E7BD5B5", "submission_order": 1, "result": "AC", "execution_time": "1091 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cnot(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AAB0E6D322171", "submission_order": 1, "result": "AC", "execution_time": "1534 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AABA6B6444264", "submission_order": 1, "result": "AC", "execution_time": "1220 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AAD302A9C7961", "submission_order": 1, "result": "AC", "execution_time": "1941 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AAD78803CC0D0", "submission_order": 1, "result": "AC", "execution_time": "1299 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB0B9244D171D", "submission_order": 1, "result": "AC", "execution_time": "1186 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x,y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB0E44D3E7D1E", "submission_order": 1, "result": "AC", "execution_time": "920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB0ED6602418D", "submission_order": 1, "result": "AC", "execution_time": "1643 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB12D86092868", "submission_order": 1, "result": "WA", "execution_time": "817 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB12D86092868", "submission_order": 2, "result": "RE", "execution_time": "1005 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.h(0)\n    qc.measure(0, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB12D86092868", "submission_order": 3, "result": "WA", "execution_time": "906 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB12D86092868", "submission_order": 4, "result": "AC", "execution_time": "1079 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.cx(x[0], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB1B1FB8CFB09", "submission_order": 1, "result": "AC", "execution_time": "1629 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB37DAEC747D1", "submission_order": 1, "result": "AC", "execution_time": "983 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB3D086AA3390", "submission_order": 1, "result": "WA", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB3D086AA3390", "submission_order": 2, "result": "AC", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB4380C93EF3F", "submission_order": 1, "result": "WA", "execution_time": "985 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(1,0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB4380C93EF3F", "submission_order": 2, "result": "RE", "execution_time": "754 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0,0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB4380C93EF3F", "submission_order": 3, "result": "AC", "execution_time": "1052 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x,y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB650BD4DE6C4", "submission_order": 1, "result": "AC", "execution_time": "1514 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB70D71B0468E", "submission_order": 1, "result": "AC", "execution_time": "1680 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB730DB3348B2", "submission_order": 1, "result": "AC", "execution_time": "1731 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB7CCFE35D5DB", "submission_order": 1, "result": "AC", "execution_time": "903 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB926F27E16BB", "submission_order": 1, "result": "AC", "execution_time": "2109 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Implement the oracle O using a CNOT gate\n    qc.cx(x[0], y[0])  # CNOT gate: x[0] controls y[0]\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB93B1B9A4BB7", "submission_order": 1, "result": "WA", "execution_time": "2268 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB93B1B9A4BB7", "submission_order": 2, "result": "AC", "execution_time": "2001 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB99F91BF760E", "submission_order": 1, "result": "WA", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AB99F91BF760E", "submission_order": 2, "result": "AC", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ABC33E84B36D4", "submission_order": 1, "result": "AC", "execution_time": "1531 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ABD75C79F53EE", "submission_order": 1, "result": "AC", "execution_time": "1614 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ABDA65B6E011E", "submission_order": 1, "result": "AC", "execution_time": "1547 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ABE5145AFBCC0", "submission_order": 1, "result": "AC", "execution_time": "845 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ABFD38611A5E2", "submission_order": 1, "result": "AC", "execution_time": "1236 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AC022298AD267", "submission_order": 1, "result": "AC", "execution_time": "2039 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_B1", "user": "AC1B72CB71DEA", "submission_order": 1, "result": "AC", "execution_time": "1598 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AC27AF2BEA13D", "submission_order": 1, "result": "AC", "execution_time": "849 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AC42F50C21D5E", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AC5104B4790C5", "submission_order": 1, "result": "AC", "execution_time": "1508 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AC6270AA96FBA", "submission_order": 1, "result": "AC", "execution_time": "1570 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AC68AD6A86EA1", "submission_order": 1, "result": "AC", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACA06550BDF51", "submission_order": 1, "result": "AC", "execution_time": "1890 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACC8D84A6B8F9", "submission_order": 1, "result": "AC", "execution_time": "1668 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACCB903942731", "submission_order": 1, "result": "AC", "execution_time": "987 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACD757FEB3665", "submission_order": 1, "result": "AC", "execution_time": "1000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACDE6BCDEED9A", "submission_order": 1, "result": "RE", "execution_time": "845 ms", "memory": "78 MiB", "code": "'''python\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACDE6BCDEED9A", "submission_order": 2, "result": "AC", "execution_time": "1206 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACE83A4756097", "submission_order": 1, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACF59C5F7BEA7", "submission_order": 1, "result": "WA", "execution_time": "850 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACF59C5F7BEA7", "submission_order": 2, "result": "AC", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ACF75CAFA94DE", "submission_order": 1, "result": "AC", "execution_time": "1516 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AD184D357EFA3", "submission_order": 1, "result": "AC", "execution_time": "1586 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AD3847B24AB25", "submission_order": 1, "result": "AC", "execution_time": "912 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AD6B538EA62DE", "submission_order": 1, "result": "AC", "execution_time": "1512 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AD91FC337B20A", "submission_order": 1, "result": "AC", "execution_time": "921 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AD95E75FEAE99", "submission_order": 1, "result": "AC", "execution_time": "1173 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AD9CC928757D0", "submission_order": 1, "result": "AC", "execution_time": "1384 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AD9EF64B673CB", "submission_order": 1, "result": "AC", "execution_time": "939 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ADD419F117F06", "submission_order": 1, "result": "RE", "execution_time": "879 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ADD419F117F06", "submission_order": 2, "result": "AC", "execution_time": "950 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ADDF8A8803211", "submission_order": 1, "result": "AC", "execution_time": "841 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ADF1DFEB366C0", "submission_order": 1, "result": "WA", "execution_time": "1443 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ADF1DFEB366C0", "submission_order": 2, "result": "AC", "execution_time": "1861 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "ADF788A818567", "submission_order": 1, "result": "AC", "execution_time": "917 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AE2ABB80CA64B", "submission_order": 1, "result": "RE", "execution_time": "1855 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,0)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AE2ABB80CA64B", "submission_order": 2, "result": "AC", "execution_time": "2111 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AE453D046AECA", "submission_order": 1, "result": "AC", "execution_time": "1702 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AE529F03B089C", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AE5580D7FF16D", "submission_order": 1, "result": "AC", "execution_time": "1837 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AE6C77D5353D4", "submission_order": 1, "result": "AC", "execution_time": "1040 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AE88A82B4EA71", "submission_order": 1, "result": "AC", "execution_time": "2338 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AEA3D8575177B", "submission_order": 1, "result": "AC", "execution_time": "883 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    # それぞれ1量子ビットを持つ量子レジスタを作成\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    # 2つの量子レジスタを持つ量子回路を作成\n    qc = QuantumCircuit(x, y)\n    \n    # 排他的論理和（XOR）を実装\n    # コントロールされたNOTゲート（CNOT）を用いて、\n    # xが|1⟩のときにのみyを反転\n    qc.cx(x[0], y[0])\n\n    return qc\n\n# 注意：このコードは、競技プログラミング向けのテンプレートであり\n# 実際には量子コンピュータもしくはシミュレータ上で実行する必要がある\n'''"}
{"problem": "QPC001_B1", "user": "AEAB71D34409B", "submission_order": 1, "result": "WA", "execution_time": "868 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AEAB71D34409B", "submission_order": 2, "result": "AC", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AEB062F2B6630", "submission_order": 1, "result": "AC", "execution_time": "965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AEB219EACA4DF", "submission_order": 1, "result": "AC", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AEB24A617196E", "submission_order": 1, "result": "AC", "execution_time": "1424 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AECD8FFA8BD28", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AED92C4908CA3", "submission_order": 1, "result": "AC", "execution_time": "1853 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n \n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AEEEE1AD53E66", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF01204D323D9", "submission_order": 1, "result": "AC", "execution_time": "857 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF05FC0F73083", "submission_order": 1, "result": "AC", "execution_time": "916 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF09CCD2C3C22", "submission_order": 1, "result": "AC", "execution_time": "1535 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF203B12A1B12", "submission_order": 1, "result": "AC", "execution_time": "902 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF251839D665F", "submission_order": 1, "result": "AC", "execution_time": "1610 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF2C9BBB1D3E4", "submission_order": 1, "result": "AC", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF3D0FFB347F6", "submission_order": 1, "result": "AC", "execution_time": "909 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF436CB7EF063", "submission_order": 1, "result": "AC", "execution_time": "1286 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF5047AF393AB", "submission_order": 1, "result": "AC", "execution_time": "1201 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF5E1386B7F00", "submission_order": 1, "result": "RE", "execution_time": "1413 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0,1)\n\n    return qc\n\n\n# 0 0 0\n# 0 1 1\n# 1 0 1\n# 1 1 0\n'''"}
{"problem": "QPC001_B1", "user": "AF5E1386B7F00", "submission_order": 2, "result": "RE", "execution_time": "1411 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x,y)\n\n    return qc\n\n\n# 0 0 0\n# 0 1 1\n# 1 0 1\n# 1 1 0\n'''"}
{"problem": "QPC001_B1", "user": "AF5E1386B7F00", "submission_order": 3, "result": "AC", "execution_time": "1398 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n\n\n# 0 0 0\n# 0 1 1\n# 1 0 1\n# 1 1 0\n'''"}
{"problem": "QPC001_B1", "user": "AF65AF489F148", "submission_order": 1, "result": "AC", "execution_time": "986 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF67F5E05A95A", "submission_order": 1, "result": "AC", "execution_time": "1580 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate\n \ndef solve() -> QuantumCircuit:\n\tx, y = QuantumRegister(1), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\t# Write your code here:\n\tqc.append(CXGate(), [0, 1])\n\treturn qc\n'''"}
{"problem": "QPC001_B1", "user": "AF868D9A3A5EF", "submission_order": 1, "result": "AC", "execution_time": "1953 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF875468CF3E9", "submission_order": 1, "result": "AC", "execution_time": "1310 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF8B1F8095FA7", "submission_order": 1, "result": "AC", "execution_time": "1265 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF92A35143E21", "submission_order": 1, "result": "AC", "execution_time": "929 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)  # 2つの量子ビットを作成\n    qc = QuantumCircuit(x, y)  # 量子回路を作成\n\n    # オラクルの実装:\n    qc.cx(x[0], y[0])  # xを制御ビット、yをターゲットビットとしてCNOTゲートを適用\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AF97B8599DD96", "submission_order": 1, "result": "AC", "execution_time": "1480 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AFA367D233CFA", "submission_order": 1, "result": "AC", "execution_time": "980 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AFA603335974F", "submission_order": 1, "result": "AC", "execution_time": "847 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AFB6CC8A57E04", "submission_order": 1, "result": "AC", "execution_time": "1660 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AFC8A0A5EBDA1", "submission_order": 1, "result": "AC", "execution_time": "1102 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AFD5F5E2C76AD", "submission_order": 1, "result": "AC", "execution_time": "1647 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AFDFB2D5C0D96", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AFF42EF494137", "submission_order": 1, "result": "AC", "execution_time": "1254 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B1", "user": "AFFA6E4F46458", "submission_order": 1, "result": "AC", "execution_time": "924 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    x, y = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A010BA07170EB", "submission_order": 1, "result": "WA", "execution_time": "975 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n        qc.mcx(list(range(n)), n)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A010BA07170EB", "submission_order": 2, "result": "WA", "execution_time": "1029 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        for j in range(n):\n            if j != i:\n                qc.x(j)\n        qc.mcx(list(range(n)), n)\n        for j in range(n):\n            if j != i:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A010BA07170EB", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A019FCA34806A", "submission_order": 1, "result": "AC", "execution_time": "1784 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A03975D9FCB4B", "submission_order": 1, "result": "AC", "execution_time": "2207 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A04B157F25C59", "submission_order": 1, "result": "AC", "execution_time": "1654 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A06F58873AEF3", "submission_order": 1, "result": "WA", "execution_time": "1027 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(n,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A06F58873AEF3", "submission_order": 2, "result": "AC", "execution_time": "1624 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0786B93205CA", "submission_order": 1, "result": "AC", "execution_time": "2294 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0799ED587737", "submission_order": 1, "result": "WA", "execution_time": "962 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cz(i,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0799ED587737", "submission_order": 2, "result": "AC", "execution_time": "2683 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 1, "result": "RE", "execution_time": "913 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in len(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 2, "result": "WA", "execution_time": "1082 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0,n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 3, "result": "WA", "execution_time": "852 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0,n-1):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 4, "result": "WA", "execution_time": "843 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0,n-1):\n        qc.cx(n,i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 5, "result": "WA", "execution_time": "958 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0,len(x)-1):\n        qc.cx(n,i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 6, "result": "WA", "execution_time": "1054 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0,len(x)-1):\n        qc.cx(i,len(x))\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 7, "result": "RE", "execution_time": "997 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(0,n-1):\n        qc.h(n).cx(i,n).h(n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 8, "result": "WA", "execution_time": "1182 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(0,n-1):\n        qc.h(n)\n        qc.cx(i,n)\n        qc.h(n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 9, "result": "WA", "execution_time": "1050 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(0,n-1):\n        qc.h(i)\n        qc.cx(i,n)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A085BBCFE1E2A", "submission_order": 10, "result": "AC", "execution_time": "1303 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 1, "result": "RE", "execution_time": "2198 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.cn(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 2, "result": "WA", "execution_time": "2035 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 3, "result": "RE", "execution_time": "1505 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.c(i + 1, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 4, "result": "WA", "execution_time": "1930 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.cx(i + 1, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 5, "result": "RE", "execution_time": "1602 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i, n + 1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 6, "result": "RE", "execution_time": "1574 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(n + 1, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 7, "result": "WA", "execution_time": "1697 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(n, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 8, "result": "WA", "execution_time": "1756 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.cx(n, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 9, "result": "WA", "execution_time": "1674 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 10, "result": "WA", "execution_time": "1465 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i + 1, 0)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A09EB08BF3436", "submission_order": 11, "result": "AC", "execution_time": "1975 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0B9CE0DBFCD9", "submission_order": 1, "result": "WA", "execution_time": "1080 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0B9CE0DBFCD9", "submission_order": 2, "result": "WA", "execution_time": "986 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0B9CE0DBFCD9", "submission_order": 3, "result": "AC", "execution_time": "2000 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in x:\n        qc.cx(i,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0D9B2C6ED62C", "submission_order": 1, "result": "AC", "execution_time": "1937 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Write your code here:\n    # CNOTゲートを使用して、xの各ビットのXORをyに制御された方法で適用します。\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    \n    return qc\n\n# 以下はプログラムをテストするための初期化ブロックです。\n# ただし、条件によってはこれは与えられたプログラムに含まれない場合があります。\nif __name__ == \"__main__\":\n    n = 3  # 例として3量子ビットのオラクルを作成します。\n    oracle_circuit = solve(n)\n    oracle_circuit.draw('mpl')\n\n    # 出力した回路の図示やシミュレーションなどは、\n    # 上記環境での実行に依存し、これは単に一例です。\n'''"}
{"problem": "QPC001_B2", "user": "A0E9770A6037E", "submission_order": 1, "result": "RE", "execution_time": "1708 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0E9770A6037E", "submission_order": 2, "result": "AC", "execution_time": "2809 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0FBBE8151A72", "submission_order": 1, "result": "AC", "execution_time": "2469 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for _ in range(n):\n        qc.cx(x[_],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0FD23F4CCF2C", "submission_order": 1, "result": "AC", "execution_time": "2516 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0FE0454A47CA", "submission_order": 1, "result": "AC", "execution_time": "1821 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A0FE4C5A4A115", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    # 各ビットに対してCNOTゲートを使用してXORを実行\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A10B257B66DA5", "submission_order": 1, "result": "RE", "execution_time": "868 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A10B257B66DA5", "submission_order": 2, "result": "AC", "execution_time": "2404 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A118B4258249B", "submission_order": 1, "result": "RE", "execution_time": "794 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n+1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A118B4258249B", "submission_order": 2, "result": "AC", "execution_time": "1541 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A12101C557F48", "submission_order": 1, "result": "AC", "execution_time": "2633 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A14E44357437D", "submission_order": 1, "result": "WA", "execution_time": "1048 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(len(x)))\n    for i in range(n):\n        qc.cx(i, n)\n    qc.h(range(len(x)))\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A14E44357437D", "submission_order": 2, "result": "WA", "execution_time": "909 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(len(x)))\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A14E44357437D", "submission_order": 3, "result": "AC", "execution_time": "1040 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A164D26F3CBB1", "submission_order": 1, "result": "AC", "execution_time": "2130 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(0, n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A168B369A7F80", "submission_order": 1, "result": "AC", "execution_time": "2211 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A1693D5E6297F", "submission_order": 1, "result": "RE", "execution_time": "1438 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # n個の量子ビットの長さ\"n\"を\"len(x)\"で取得する。\n    n = len(x)\n\n    #n個の各量子ビットを制御ビットとして、1量子ビットに制御Xゲートを作用させる。\n    for i in n:\n        qc.cx(x[i],n)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A1693D5E6297F", "submission_order": 2, "result": "RE", "execution_time": "1378 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # n個の量子ビットの長さ\"n\"を\"len(x)\"で取得する。\n    n = len(x)\n\n    #n個の各量子ビットを制御ビットとして、1量子ビットに制御Xゲートを作用させる。\n    i = 0\n    for i in n-1:\n        qc.cx(x[i],n)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A1693D5E6297F", "submission_order": 3, "result": "RE", "execution_time": "1386 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # n個の量子ビットの長さ\"n\"を\"len(x)\"で取得する。\n    n = len(x)\n\n    #n個の各量子ビットを制御ビットとして、1量子ビットに制御Xゲートを作用させる。\n    i = 0\n    for i in n-1:\n        qc.cx(x[i],y)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A1693D5E6297F", "submission_order": 4, "result": "RE", "execution_time": "1214 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # n個の量子ビットの長さ\"n\"を\"len(x)\"で取得する。\n    n = len(x)\n\n    #n個の各量子ビットを制御ビットとして、1量子ビットに制御Xゲートを作用させる。\n    i = 0\n    for i in lange(n):\n        qc.cx(x[i],y)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A1693D5E6297F", "submission_order": 5, "result": "AC", "execution_time": "2941 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # n個の量子ビットの長さ\"n\"を\"len(x)\"で取得する。\n    n = len(x)\n\n    #n個の各量子ビットを制御ビットとして、1量子ビットに制御Xゲートを作用させる。\n    i = 0\n    for i in range(n):\n        qc.cx(x[i],y)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A1C07A8527177", "submission_order": 1, "result": "AC", "execution_time": "1499 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A1C47024A6CB2", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A1D8FF1ACC75A", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A20797EE668B1", "submission_order": 1, "result": "AC", "execution_time": "2727 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A21BE8FC96864", "submission_order": 1, "result": "AC", "execution_time": "1783 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(len(x)):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A226231E2F72A", "submission_order": 1, "result": "AC", "execution_time": "1769 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A243656C2547F", "submission_order": 1, "result": "AC", "execution_time": "2866 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    length = len(x)\n    for i in range(length):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A24AF15D643CE", "submission_order": 1, "result": "AC", "execution_time": "1395 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A26492F9B5DA8", "submission_order": 1, "result": "AC", "execution_time": "1397 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A26C2AF5F263B", "submission_order": 1, "result": "AC", "execution_time": "1514 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A26F037BF89DB", "submission_order": 1, "result": "AC", "execution_time": "1515 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A27E9494CAB3C", "submission_order": 1, "result": "AC", "execution_time": "1725 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A28558CC865DF", "submission_order": 1, "result": "AC", "execution_time": "1854 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A289B161947DB", "submission_order": 1, "result": "AC", "execution_time": "3666 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A29B6A1C027AC", "submission_order": 1, "result": "AC", "execution_time": "3576 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A2BE84AC4BE93", "submission_order": 1, "result": "AC", "execution_time": "1631 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A2DE223ACCAFB", "submission_order": 1, "result": "AC", "execution_time": "3074 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A2E421CFC39A4", "submission_order": 1, "result": "AC", "execution_time": "2194 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A2F53008679D6", "submission_order": 1, "result": "RE", "execution_time": "2929 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x(i),y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A2F53008679D6", "submission_order": 2, "result": "AC", "execution_time": "2062 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A3044BC547A90", "submission_order": 1, "result": "AC", "execution_time": "1856 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n \n    for i in range(n):\n      qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A320FCAE9B29F", "submission_order": 1, "result": "WA", "execution_time": "1984 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, n-1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A320FCAE9B29F", "submission_order": 2, "result": "AC", "execution_time": "2275 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A3245D14E93A6", "submission_order": 1, "result": "AC", "execution_time": "1515 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A338EB30298AD", "submission_order": 1, "result": "AC", "execution_time": "1724 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A33A6DC693036", "submission_order": 1, "result": "AC", "execution_time": "2031 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A33B915C28A5C", "submission_order": 1, "result": "RE", "execution_time": "1440 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n       qc.cx(x[i],y[i]) \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A33B915C28A5C", "submission_order": 2, "result": "AC", "execution_time": "3753 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n       qc.cx(x[i],y[0]) \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A34B099DB3822", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Apply CNOT gates from each x_i to y\n    for i in range(n):\n        qc.cx(x[i], y[0])  # CNOT from x[i] to y\n    \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A365D26CE42AF", "submission_order": 1, "result": "WA", "execution_time": "970 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A365D26CE42AF", "submission_order": 2, "result": "AC", "execution_time": "1691 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A3723D203EE8A", "submission_order": 1, "result": "AC", "execution_time": "4846 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for idx in range(n):\n        qc.cx(x[idx], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A3734C2E67A44", "submission_order": 1, "result": "WA", "execution_time": "1060 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(y,x[i])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A3734C2E67A44", "submission_order": 2, "result": "AC", "execution_time": "2205 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A37AB426BDAE9", "submission_order": 1, "result": "WA", "execution_time": "1008 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[0], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A37AB426BDAE9", "submission_order": 2, "result": "AC", "execution_time": "1933 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A38050EAC7ADD", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A39D6558F3130", "submission_order": 1, "result": "AC", "execution_time": "2363 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A3CAB31084915", "submission_order": 1, "result": "AC", "execution_time": "3448 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A3DD833BA2112", "submission_order": 1, "result": "AC", "execution_time": "3683 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A40DC060DCC50", "submission_order": 1, "result": "AC", "execution_time": "2660 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A41CBECF13817", "submission_order": 1, "result": "AC", "execution_time": "1954 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A41DF46573DFC", "submission_order": 1, "result": "AC", "execution_time": "2431 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A439554872180", "submission_order": 1, "result": "WA", "execution_time": "1166 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n      qc.cx(y, x[i])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A439554872180", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n      qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A43D01FCBD209", "submission_order": 1, "result": "AC", "execution_time": "1846 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A463C73238FBE", "submission_order": 1, "result": "WA", "execution_time": "2394 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(y,x)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A463C73238FBE", "submission_order": 2, "result": "AC", "execution_time": "1803 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4714304619C1", "submission_order": 1, "result": "RE", "execution_time": "2081 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.ccx(0,1,2)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4714304619C1", "submission_order": 2, "result": "AC", "execution_time": "2350 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A47BB18D4F2F9", "submission_order": 1, "result": "WA", "execution_time": "1861 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A47BB18D4F2F9", "submission_order": 2, "result": "AC", "execution_time": "1979 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A48848A673DB6", "submission_order": 1, "result": "AC", "execution_time": "2959 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A48AAA1E52C8A", "submission_order": 1, "result": "RE", "execution_time": "785 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cnot(i,len(n))\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A48AAA1E52C8A", "submission_order": 2, "result": "RE", "execution_time": "969 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cnot(i,len(n))\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A48AAA1E52C8A", "submission_order": 3, "result": "AC", "execution_time": "2174 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cnot(i,n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4959B33D0978", "submission_order": 1, "result": "RE", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4959B33D0978", "submission_order": 2, "result": "RE", "execution_time": "1005 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(n,2)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4959B33D0978", "submission_order": 3, "result": "AC", "execution_time": "1861 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4A154DEDF256", "submission_order": 1, "result": "WA", "execution_time": "908 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(y,x)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4A154DEDF256", "submission_order": 2, "result": "RE", "execution_time": "742 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(y,x)\n    qc.iden(x)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4A154DEDF256", "submission_order": 3, "result": "AC", "execution_time": "1926 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4A30925DC267", "submission_order": 1, "result": "RE", "execution_time": "2147 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0, 2)\n    qc.cx(1, 2)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4A30925DC267", "submission_order": 2, "result": "AC", "execution_time": "2332 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4A81088416B4", "submission_order": 1, "result": "AC", "execution_time": "2173 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4B36DF30674A", "submission_order": 1, "result": "WA", "execution_time": "1682 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n      qc.cx(y, x[i])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4B36DF30674A", "submission_order": 2, "result": "AC", "execution_time": "2301 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n      qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4C18C68AE300", "submission_order": 1, "result": "AC", "execution_time": "1322 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4C740B03A209", "submission_order": 1, "result": "RE", "execution_time": "925 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x.index(i),y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4C740B03A209", "submission_order": 2, "result": "AC", "execution_time": "1784 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4C9B21FB377F", "submission_order": 1, "result": "AC", "execution_time": "1576 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4CB27DFC5C9E", "submission_order": 1, "result": "AC", "execution_time": "2738 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4CB8ABF740C4", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4CC6850F8209", "submission_order": 1, "result": "AC", "execution_time": "1730 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4FD3766EA1A6", "submission_order": 1, "result": "AC", "execution_time": "1393 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A4FFB65A7437E", "submission_order": 1, "result": "AC", "execution_time": "2536 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A50EAB206D486", "submission_order": 1, "result": "AC", "execution_time": "1663 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A51958006A5E4", "submission_order": 1, "result": "AC", "execution_time": "1991 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A52DA06B89B51", "submission_order": 1, "result": "AC", "execution_time": "1721 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A53D2A4DB4D9A", "submission_order": 1, "result": "AC", "execution_time": "4275 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5443292B147E", "submission_order": 1, "result": "AC", "execution_time": "2330 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A54D7BFC9DE67", "submission_order": 1, "result": "AC", "execution_time": "2294 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.cnot(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A56AE9904CEC5", "submission_order": 1, "result": "AC", "execution_time": "1513 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A57020BFF845C", "submission_order": 1, "result": "RE", "execution_time": "855 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A57020BFF845C", "submission_order": 2, "result": "AC", "execution_time": "2026 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5720DA265C5F", "submission_order": 1, "result": "AC", "execution_time": "1798 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A575ECB3423C1", "submission_order": 1, "result": "AC", "execution_time": "2065 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    for i in range(n):\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58678F337760", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58678F337760", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58678F337760", "submission_order": 3, "result": "TLE", "execution_time": "3000 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for xi in x:\n        qc.cx(xi,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58678F337760", "submission_order": 4, "result": "TLE", "execution_time": "3000 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for xi in x:\n        qc.cx(xi,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58678F337760", "submission_order": 5, "result": "TLE", "execution_time": "3000 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n \n    for i in range(n):\n      qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58678F337760", "submission_order": 6, "result": "TLE", "execution_time": "3000 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for xi in x:\n        qc.cx(xi,y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58678F337760", "submission_order": 7, "result": "TLE", "execution_time": "3000 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for xi in x:\n        qc.cx(xi, y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58678F337760", "submission_order": 8, "result": "AC", "execution_time": "2668 ms", "memory": "287 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for xi in x:\n        qc.cx(xi, y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A58E21BFE12E1", "submission_order": 1, "result": "AC", "execution_time": "1604 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A596D63BAACAB", "submission_order": 1, "result": "AC", "execution_time": "2389 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A599E04354402", "submission_order": 1, "result": "AC", "execution_time": "1857 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A59EE7D042EDA", "submission_order": 1, "result": "AC", "execution_time": "2088 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for _ in range(n):\n        qc.cx(x[_],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5C40535E04F8", "submission_order": 1, "result": "AC", "execution_time": "1816 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5C7EF00C1C81", "submission_order": 1, "result": "AC", "execution_time": "2127 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5D7789928A96", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5DED096DBEBD", "submission_order": 1, "result": "AC", "execution_time": "2431 ms", "memory": "163 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n\n    qc.cx(range(n), n)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5E235DAB1943", "submission_order": 1, "result": "AC", "execution_time": "2813 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0]) \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5EEC1D8325CE", "submission_order": 1, "result": "WA", "execution_time": "1522 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(y, x[i])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5EEC1D8325CE", "submission_order": 2, "result": "AC", "execution_time": "1659 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A5F86933E19BD", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "287 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n \n    for i in range(n):\n      qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A605331F6EBF2", "submission_order": 1, "result": "AC", "execution_time": "1429 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A61004B377DD5", "submission_order": 1, "result": "RE", "execution_time": "853 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A61004B377DD5", "submission_order": 2, "result": "RE", "execution_time": "948 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(i+1,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A61004B377DD5", "submission_order": 3, "result": "AC", "execution_time": "2724 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A613B6722C878", "submission_order": 1, "result": "AC", "execution_time": "2088 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A61A34D2A4B87", "submission_order": 1, "result": "AC", "execution_time": "2608 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cnot(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A620408773A80", "submission_order": 1, "result": "AC", "execution_time": "1988 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A621ADCD4E30B", "submission_order": 1, "result": "RE", "execution_time": "1911 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[range(n)], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A621ADCD4E30B", "submission_order": 2, "result": "AC", "execution_time": "3481 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    [qc.cx(x[i], y) for i in range(n)]\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A62484D199B1E", "submission_order": 1, "result": "AC", "execution_time": "1443 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for xi in x:\n        qc.cx(xi, y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6259279BF174", "submission_order": 1, "result": "RE", "execution_time": "997 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n + 1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6259279BF174", "submission_order": 2, "result": "AC", "execution_time": "1941 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6346EB3C042D", "submission_order": 1, "result": "RE", "execution_time": "2001 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i,x)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6346EB3C042D", "submission_order": 2, "result": "AC", "execution_time": "2052 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A635BCD4FBF0B", "submission_order": 1, "result": "WA", "execution_time": "961 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.mct(x[:], y[0], None, mode='noancilla')\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A635BCD4FBF0B", "submission_order": 2, "result": "WA", "execution_time": "930 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.mct(x, y[0], None, mode='noancilla')\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A635BCD4FBF0B", "submission_order": 3, "result": "AC", "execution_time": "2206 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A644343BA5A34", "submission_order": 1, "result": "AC", "execution_time": "2033 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A64B8590BAAF5", "submission_order": 1, "result": "RE", "execution_time": "1358 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(len(x)):\n        qc.cx(x[i])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A64B8590BAAF5", "submission_order": 2, "result": "AC", "execution_time": "1804 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(len(x)):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A664692B77924", "submission_order": 1, "result": "AC", "execution_time": "2548 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A667F244ACA3C", "submission_order": 1, "result": "RE", "execution_time": "776 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x))\n        qc.cx(i,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A667F244ACA3C", "submission_order": 2, "result": "RE", "execution_time": "861 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x))\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A667F244ACA3C", "submission_order": 3, "result": "RE", "execution_time": "1102 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x))\n        qc.cx(x[i],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A667F244ACA3C", "submission_order": 4, "result": "AC", "execution_time": "1657 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A670892B5DA63", "submission_order": 1, "result": "AC", "execution_time": "2784 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A67637CB6B5CF", "submission_order": 1, "result": "AC", "execution_time": "2156 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A68011A32CB7C", "submission_order": 1, "result": "RE", "execution_time": "2010 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in n:\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A68011A32CB7C", "submission_order": 2, "result": "AC", "execution_time": "2290 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6935842A5D8E", "submission_order": 1, "result": "AC", "execution_time": "2362 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A69899009F9FA", "submission_order": 1, "result": "AC", "execution_time": "1315 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A69C1E52F98D6", "submission_order": 1, "result": "WA", "execution_time": "1644 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,n-1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A69C1E52F98D6", "submission_order": 2, "result": "WA", "execution_time": "1333 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,n-1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A69C1E52F98D6", "submission_order": 3, "result": "RE", "execution_time": "1198 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n+1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A69C1E52F98D6", "submission_order": 4, "result": "AC", "execution_time": "2767 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6A68490A8C1C", "submission_order": 1, "result": "RE", "execution_time": "1362 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6A68490A8C1C", "submission_order": 2, "result": "AC", "execution_time": "3608 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6D33DE46A758", "submission_order": 1, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6D33DE46A758", "submission_order": 2, "result": "AC", "execution_time": "1664 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6EE30EFFE416", "submission_order": 1, "result": "RE", "execution_time": "931 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    n = len(x)\n    for i in n:\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A6F64C1B18C54", "submission_order": 1, "result": "AC", "execution_time": "2333 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A70D5A5E27E5D", "submission_order": 1, "result": "AC", "execution_time": "1860 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A716973B44F1D", "submission_order": 1, "result": "AC", "execution_time": "2474 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A77D90D1D6A3E", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A77D90D1D6A3E", "submission_order": 2, "result": "MLE", "execution_time": "2998 ms", "memory": "512 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A77D90D1D6A3E", "submission_order": 3, "result": "AC", "execution_time": "2357 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for xi in x:\n        qc.cx(xi, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7818E8AA3BEB", "submission_order": 1, "result": "RE", "execution_time": "960 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    nn = len(x)\n    for i in range(nn):\n        gc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7818E8AA3BEB", "submission_order": 2, "result": "RE", "execution_time": "838 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        gc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7818E8AA3BEB", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    nn = len(x)\n    for i in range(nn):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7832EAE71A38", "submission_order": 1, "result": "AC", "execution_time": "2169 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i], y)\n    \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7848199A8F97", "submission_order": 1, "result": "AC", "execution_time": "1277 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A785158CD2E06", "submission_order": 1, "result": "WA", "execution_time": "1006 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(i, n - 1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A785158CD2E06", "submission_order": 2, "result": "AC", "execution_time": "2093 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A789BFA6F23D3", "submission_order": 1, "result": "AC", "execution_time": "1644 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\ndef solve(n: int) -> QuantumCircuit:\n  x, y = QuantumRegister(n), QuantumRegister(1)\n  qc = QuantumCircuit(x, y)\n  for i in range(n):\n    qc.cx(i, n)\n  return qc\n'''"}
{"problem": "QPC001_B2", "user": "A79747371C33B", "submission_order": 1, "result": "AC", "execution_time": "2298 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A79A9DC11F5D3", "submission_order": 1, "result": "AC", "execution_time": "1991 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7B9639C65610", "submission_order": 1, "result": "RE", "execution_time": "1448 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[range(n)],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7B9639C65610", "submission_order": 2, "result": "AC", "execution_time": "2031 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for _ in range(n):\n        qc.cx(x[_],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7C0FB71C66ED", "submission_order": 1, "result": "AC", "execution_time": "2292 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7C7B6E07DEAC", "submission_order": 1, "result": "AC", "execution_time": "2008 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n): qc.cx(x[i], n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7D2770B55096", "submission_order": 1, "result": "AC", "execution_time": "1736 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7D72E5C265EA", "submission_order": 1, "result": "AC", "execution_time": "1809 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A7EFB02E5487C", "submission_order": 1, "result": "AC", "execution_time": "1841 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i],n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A813432090E82", "submission_order": 1, "result": "RE", "execution_time": "2898 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[range(n)], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A813432090E82", "submission_order": 2, "result": "RE", "execution_time": "1860 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[range(n)], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A813432090E82", "submission_order": 3, "result": "AC", "execution_time": "2376 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A814EC8151EFA", "submission_order": 1, "result": "WA", "execution_time": "937 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.mcx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A814EC8151EFA", "submission_order": 2, "result": "WA", "execution_time": "888 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A814EC8151EFA", "submission_order": 3, "result": "AC", "execution_time": "1260 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A81873060C404", "submission_order": 1, "result": "AC", "execution_time": "1062 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A821E1C25746C", "submission_order": 1, "result": "AC", "execution_time": "1766 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A825816290066", "submission_order": 1, "result": "RE", "execution_time": "944 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n-1)\n    qc.cx(y[i+1], x[i+1])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A825816290066", "submission_order": 2, "result": "AC", "execution_time": "1104 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n      qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A835D1E0DE7D2", "submission_order": 1, "result": "AC", "execution_time": "3704 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A87871B4456B1", "submission_order": 1, "result": "AC", "execution_time": "1704 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A87CC7F64755B", "submission_order": 1, "result": "AC", "execution_time": "2169 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8973F4971702", "submission_order": 1, "result": "WA", "execution_time": "894 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n): qc.cx(i, i + 1)\n    for i in range(n - 1): qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8973F4971702", "submission_order": 2, "result": "AC", "execution_time": "1503 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n): qc.cx(i, n)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8A7E96AE9F13", "submission_order": 1, "result": "AC", "execution_time": "1648 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8AF109076E09", "submission_order": 1, "result": "RE", "execution_time": "948 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i],0)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8AF109076E09", "submission_order": 2, "result": "RE", "execution_time": "916 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i]+1,0)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8AF109076E09", "submission_order": 3, "result": "AC", "execution_time": "1657 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i],n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8B0E6EDC7FF2", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n     for i in range(n):\n        qc.cx(i,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8B0E6EDC7FF2", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n     for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8B0E6EDC7FF2", "submission_order": 3, "result": "AC", "execution_time": "2967 ms", "memory": "287 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8C0B88C15EE4", "submission_order": 1, "result": "WA", "execution_time": "1723 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.cx(n-1,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8C0B88C15EE4", "submission_order": 2, "result": "AC", "execution_time": "1979 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8CD7DDDA5623", "submission_order": 1, "result": "AC", "execution_time": "1972 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8CF912261CA7", "submission_order": 1, "result": "AC", "execution_time": "1556 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(len(x)):\n        qc.cx(x[i],y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8D9C43903D22", "submission_order": 1, "result": "RE", "execution_time": "890 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in n:\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8D9C43903D22", "submission_order": 2, "result": "AC", "execution_time": "1616 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8E25A7263F15", "submission_order": 1, "result": "WA", "execution_time": "2181 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8E25A7263F15", "submission_order": 2, "result": "RE", "execution_time": "1209 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n+1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8E25A7263F15", "submission_order": 3, "result": "WA", "execution_time": "1303 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i, i+1)\n\n    qc.cx(n-1, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8E25A7263F15", "submission_order": 4, "result": "AC", "execution_time": "3000 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A8EA86F340A20", "submission_order": 1, "result": "AC", "execution_time": "1927 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n      qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A908332D0EC5E", "submission_order": 1, "result": "RE", "execution_time": "920 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    circuit.h(0)\n    circuit.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A908332D0EC5E", "submission_order": 2, "result": "AC", "execution_time": "1913 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])  # 各 x_i と y の間に CX ゲートを配置\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A91F72CD05284", "submission_order": 1, "result": "AC", "execution_time": "2053 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i, n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A93F83BAE7486", "submission_order": 1, "result": "AC", "execution_time": "1491 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    for i in range(n):\n        qc.cx(i, n)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A940DCA799D38", "submission_order": 1, "result": "AC", "execution_time": "2318 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A944B2E2179D0", "submission_order": 1, "result": "AC", "execution_time": "1470 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 1, "result": "RE", "execution_time": "841 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in n:\n        qc.h(x[i])\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 2, "result": "WA", "execution_time": "878 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(x[i])\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 3, "result": "WA", "execution_time": "957 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(x[i])\n    for i in range(n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 4, "result": "RE", "execution_time": "768 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,11):\n        qc.h(x[i])\n    for i in range(1,11):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 5, "result": "RE", "execution_time": "911 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,11):\n        qc.h(x[i])\n    for i in range(1,11):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 6, "result": "RE", "execution_time": "895 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,11):\n        qc.h(x[i])\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 7, "result": "RE", "execution_time": "913 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n+1):\n        qc.h(x[i])\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 8, "result": "RE", "execution_time": "866 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n+1):\n        qc.h(x[i])\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 9, "result": "WA", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        qc.h(x[i])\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 10, "result": "WA", "execution_time": "858 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        qc.h(x[i])\n    for i in range(1,n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 11, "result": "RE", "execution_time": "813 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n,x)\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        qc.h(x[i])\n    for i in range(1,n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 12, "result": "RE", "execution_time": "779 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n,'x'),\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        qc.h(x[i])\n    for i in range(1,n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 13, "result": "WA", "execution_time": "1169 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n,'x')\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        qc.h(x[i])\n    for i in range(1,n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 14, "result": "WA", "execution_time": "906 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n,'x')\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        qc.h(x[i])\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 15, "result": "RE", "execution_time": "876 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n,'x')\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        qc.cnot(qc.h(x[i]),y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 16, "result": "RE", "execution_time": "791 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n,'x')\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        z= qc.h(x[i])\n        qc.cnot(z,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 17, "result": "WA", "execution_time": "963 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n,'x')\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(1,n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 18, "result": "RE", "execution_time": "929 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n,'x')\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n+1):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 19, "result": "WA", "execution_time": "955 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A951785617D0F", "submission_order": 20, "result": "AC", "execution_time": "1777 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A99902AF71380", "submission_order": 1, "result": "WA", "execution_time": "2086 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n-1):\n        qc.cx(x[i],x[i+1])\n    qc.cx(x[n-1],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A99902AF71380", "submission_order": 2, "result": "WA", "execution_time": "1837 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n-1):\n        qc.cx(x[i],x[i+1])\n    qc.cx(x[n-1],y)\n    for i in range(n-1):\n        qc.cx(x[i],x[i+1])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A99902AF71380", "submission_order": 3, "result": "AC", "execution_time": "2397 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n-1):\n        qc.cx(x[i],x[i+1])\n    qc.cx(x[n-1],y)\n    for i in range(n-1):\n        qc.cx(x[n-i-2],x[n-i-1])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A99980356BFF7", "submission_order": 1, "result": "WA", "execution_time": "1075 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.cx(x[i], x[i + 1])\n\n    qc.cx(x[n - 1], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A99980356BFF7", "submission_order": 2, "result": "AC", "execution_time": "2019 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9A84D1A7C68E", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n)\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9A84D1A7C68E", "submission_order": 2, "result": "AC", "execution_time": "1796 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9CAE624D5B00", "submission_order": 1, "result": "WA", "execution_time": "1048 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.mcx(x, y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9CAE624D5B00", "submission_order": 2, "result": "AC", "execution_time": "2720 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.mcx([range(n)], n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 3, "result": "WA", "execution_time": "1128 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 4, "result": "WA", "execution_time": "1308 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 5, "result": "TLE", "execution_time": "3000 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 6, "result": "TLE", "execution_time": "3000 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 7, "result": "TLE", "execution_time": "3000 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 8, "result": "TLE", "execution_time": "3000 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 9, "result": "TLE", "execution_time": "3000 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "A9F843EBFA4AD", "submission_order": 10, "result": "AC", "execution_time": "2925 ms", "memory": "287 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for xi in x:\n        qc.cx(xi, y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA0C9C84742C7", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA13AD79666A3", "submission_order": 1, "result": "AC", "execution_time": "1576 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA13D1EF152EE", "submission_order": 1, "result": "WA", "execution_time": "1104 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cx(i, 0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA13D1EF152EE", "submission_order": 2, "result": "WA", "execution_time": "952 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0, n - 1):\n        qc.cx(i, n - 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA13D1EF152EE", "submission_order": 3, "result": "WA", "execution_time": "1032 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1, n + 1):\n        qc.cx(i, 0)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA13D1EF152EE", "submission_order": 4, "result": "AC", "execution_time": "2034 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA215FDAF7F5A", "submission_order": 1, "result": "AC", "execution_time": "2755 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA2E0FB06CDCA", "submission_order": 1, "result": "AC", "execution_time": "2368 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA37F09117AF5", "submission_order": 1, "result": "AC", "execution_time": "1960 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA39C3A8FB3D2", "submission_order": 1, "result": "AC", "execution_time": "2837 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA3A8E216AB3C", "submission_order": 1, "result": "AC", "execution_time": "2609 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA50DCFB8392F", "submission_order": 1, "result": "AC", "execution_time": "2406 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA62093CC5BC4", "submission_order": 1, "result": "AC", "execution_time": "1760 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AA808057E3209", "submission_order": 1, "result": "AC", "execution_time": "2124 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AAA208DF7B53D", "submission_order": 1, "result": "RE", "execution_time": "1063 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x[0:n], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AAA208DF7B53D", "submission_order": 2, "result": "AC", "execution_time": "2491 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0:n], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AAA2176057FA9", "submission_order": 1, "result": "RE", "execution_time": "785 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n=len(x)\n    for i in range(n)\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AAA2176057FA9", "submission_order": 2, "result": "AC", "execution_time": "1881 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n=len(x)\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AAAE9A165561E", "submission_order": 1, "result": "AC", "execution_time": "2022 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AABC520873FAB", "submission_order": 1, "result": "AC", "execution_time": "1677 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in x:\n        qc.cnot(i,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AAC9E8B4EA878", "submission_order": 1, "result": "AC", "execution_time": "1416 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tfor i in range(n):\n\t\tqc.cx(x[i], y)\n\treturn qc\n'''"}
{"problem": "QPC001_B2", "user": "AADB22D0249A0", "submission_order": 1, "result": "WA", "execution_time": "1095 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cx(0, i)\n        \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AADB22D0249A0", "submission_order": 2, "result": "WA", "execution_time": "800 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0, n - 1):\n        qc.cx(i, n - 1)\n        \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AADB22D0249A0", "submission_order": 3, "result": "WA", "execution_time": "834 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cx(i, 0)\n        \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AADB22D0249A0", "submission_order": 4, "result": "WA", "execution_time": "962 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cx(0, i)\n        \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AADB22D0249A0", "submission_order": 5, "result": "WA", "execution_time": "1029 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0, n - 1):\n        qc.cx(n - 1, i)\n        \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AADB22D0249A0", "submission_order": 6, "result": "AC", "execution_time": "2100 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0, n):\n        qc.cx(x[i], y)\n        \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AAEDB3F52559A", "submission_order": 1, "result": "AC", "execution_time": "1697 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB0EF784A1FA0", "submission_order": 1, "result": "RE", "execution_time": "906 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB0EF784A1FA0", "submission_order": 2, "result": "WA", "execution_time": "887 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB1366755534F", "submission_order": 1, "result": "AC", "execution_time": "2548 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i], y)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB14F4F0C6208", "submission_order": 1, "result": "AC", "execution_time": "1770 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(range(n),y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB2C8B379D0A7", "submission_order": 1, "result": "AC", "execution_time": "1707 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i],y[0])\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB417C0973797", "submission_order": 1, "result": "AC", "execution_time": "1893 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n \n    for i in range(n):\n      qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB46CCB2BDCA4", "submission_order": 1, "result": "RE", "execution_time": "1492 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    circ = QuantumCircuit(x, y)\n    # Write your code here:\n\n    circ = QuantumCircuit(2)\n    for i in range(n):\n        circ.cx(i, n)\n    return circ\n'''"}
{"problem": "QPC001_B2", "user": "AB46CCB2BDCA4", "submission_order": 2, "result": "AC", "execution_time": "3607 ms", "memory": "289 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    circ = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        circ.cx(i, n)\n    return circ\n'''"}
{"problem": "QPC001_B2", "user": "AB5AAE4A14296", "submission_order": 1, "result": "AC", "execution_time": "1612 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(i, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB5F0A2140B7E", "submission_order": 1, "result": "WA", "execution_time": "956 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1, n+1):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB5F0A2140B7E", "submission_order": 2, "result": "WA", "execution_time": "915 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1, n+1):\n        qc.cx(i, 0)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB5F0A2140B7E", "submission_order": 3, "result": "AC", "execution_time": "1660 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB63CB0233B06", "submission_order": 1, "result": "WA", "execution_time": "1518 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(0,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB63CB0233B06", "submission_order": 2, "result": "WA", "execution_time": "1588 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(n,0)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB63CB0233B06", "submission_order": 3, "result": "AC", "execution_time": "1774 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB68DE565F007", "submission_order": 1, "result": "AC", "execution_time": "2962 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB7A7144B61EE", "submission_order": 1, "result": "AC", "execution_time": "2186 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i],y[0])\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB7D2521D3364", "submission_order": 1, "result": "WA", "execution_time": "842 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB7D2521D3364", "submission_order": 2, "result": "AC", "execution_time": "2825 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB8D577E17C01", "submission_order": 1, "result": "RE", "execution_time": "899 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in n:\n        qc.cx(i,y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB8D577E17C01", "submission_order": 2, "result": "WA", "execution_time": "953 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(y,i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AB8D577E17C01", "submission_order": 3, "result": "AC", "execution_time": "1803 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ABA9A8C0418A0", "submission_order": 1, "result": "AC", "execution_time": "2338 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ABD760D25F3AB", "submission_order": 1, "result": "AC", "execution_time": "2708 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Apply CX\n    for i in range(n):\n        qc.cx(control_qubit=x[i], target_qubit=y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ABF348EF4F41C", "submission_order": 1, "result": "AC", "execution_time": "2641 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\n#from qiskit.quantum_info import Statevector\nimport numpy as np\n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n \n    return qc\n \nqc = solve(10)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC001_B2", "user": "AC00EBCAA9931", "submission_order": 1, "result": "AC", "execution_time": "2657 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i],y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC05C2AA3D72B", "submission_order": 1, "result": "AC", "execution_time": "1331 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC09142503836", "submission_order": 1, "result": "RE", "execution_time": "867 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for x_qubit in range(n):\n        qc.x(x_qubit, n+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC09142503836", "submission_order": 2, "result": "RE", "execution_time": "916 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for x_qubit in range(n):\n        qc.x(x_qubit, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC09142503836", "submission_order": 3, "result": "AC", "execution_time": "1411 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for x_qubit in range(n):\n        qc.cx(x_qubit, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC0F6D8888CD9", "submission_order": 1, "result": "AC", "execution_time": "2031 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC1F24F24B42D", "submission_order": 1, "result": "AC", "execution_time": "3576 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC217D16CF732", "submission_order": 1, "result": "RE", "execution_time": "1081 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC217D16CF732", "submission_order": 2, "result": "RE", "execution_time": "798 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i],n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC217D16CF732", "submission_order": 3, "result": "RE", "execution_time": "905 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(i,n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC217D16CF732", "submission_order": 4, "result": "AC", "execution_time": "1870 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC53B40E20A1B", "submission_order": 1, "result": "AC", "execution_time": "1809 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.cx(x, y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC63F72879BC2", "submission_order": 1, "result": "AC", "execution_time": "2274 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AC79CAC52F35E", "submission_order": 1, "result": "AC", "execution_time": "1122 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACADDED8EF98A", "submission_order": 1, "result": "AC", "execution_time": "1994 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACB113A9EE21A", "submission_order": 1, "result": "RE", "execution_time": "847 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.xc(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACB113A9EE21A", "submission_order": 2, "result": "AC", "execution_time": "2299 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACB80F78A76FE", "submission_order": 1, "result": "AC", "execution_time": "2927 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACC8D394D764D", "submission_order": 1, "result": "WA", "execution_time": "966 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cx(0,i)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACC8D394D764D", "submission_order": 2, "result": "WA", "execution_time": "1137 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,n-1)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACC8D394D764D", "submission_order": 3, "result": "WA", "execution_time": "829 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cx(0,i)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACC8D394D764D", "submission_order": 4, "result": "WA", "execution_time": "862 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cx(i-1,i)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACC8D394D764D", "submission_order": 5, "result": "WA", "execution_time": "936 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cx(0,i)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACC8D394D764D", "submission_order": 6, "result": "WA", "execution_time": "1175 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1,n+1):\n        qc.cx(0,i)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACCB459434B53", "submission_order": 1, "result": "WA", "execution_time": "2149 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACCB459434B53", "submission_order": 2, "result": "RE", "execution_time": "1702 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACCB459434B53", "submission_order": 3, "result": "AC", "execution_time": "2223 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACCBF96B469D3", "submission_order": 1, "result": "RE", "execution_time": "894 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACCBF96B469D3", "submission_order": 2, "result": "RE", "execution_time": "924 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], yo)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACCBF96B469D3", "submission_order": 3, "result": "AC", "execution_time": "1850 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACD510AE77BFF", "submission_order": 1, "result": "AC", "execution_time": "1798 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in x:\n        qc.cx(i, y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACD79FDA38205", "submission_order": 1, "result": "WA", "execution_time": "1633 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACD79FDA38205", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n=len(x)\n    if n=1:\n        qc.cx(0,1)\n    elif n=2:\n        qc.cx(0,2)\n        qc.cx(1,2)\n    elif n=3:\n        qc.cx(0,3)\n        qc.cx(1,3)\n        qc.cx(2,3)\n    elif n=4:\n        for i in range(4):\n            qc.cx(i,4)\n    \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACD79FDA38205", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n=len(x)\n    if n=1:\n        qc.cx(0,1)\n    elif n=2:\n        qc.cx(0,2)\n        qc.cx(1,2)\n    elif n=3:\n        qc.cx(0,3)\n        qc.cx(1,3)\n        qc.cx(2,3)\n    elif n=4:\n        qc.cx(0,4)\n        qc.cx(1,4)\n        qc.cx(2,4)\n        qc.cx(3,4)\n    \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACD79FDA38205", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n=len(x)\n    if n=1:\n        qc.cx(0,1)\n    elif n=2:\n        qc.cx(0,2)\n        qc.cx(1,2)\n    elif n=3:\n        qc.cx(0,3)\n        qc.cx(1,3)\n        qc.cx(2,3)\n    elif n=4:\n        qc.cx(0,4)\n        qc.cx(1,4)\n        qc.cx(2,4)\n        qc.cx(3,4)\n    \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACD79FDA38205", "submission_order": 5, "result": "AC", "execution_time": "1728 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACDF1030E7C3D", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACE0289A93822", "submission_order": 1, "result": "AC", "execution_time": "2664 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACE9B32AC9EAE", "submission_order": 1, "result": "WA", "execution_time": "916 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(n, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACE9B32AC9EAE", "submission_order": 2, "result": "AC", "execution_time": "1679 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACF4B7ACEF556", "submission_order": 1, "result": "AC", "execution_time": "2822 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0, n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ACF6E7890086A", "submission_order": 1, "result": "AC", "execution_time": "2796 ms", "memory": "288 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD15D02BEB355", "submission_order": 1, "result": "AC", "execution_time": "1750 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD340F5581503", "submission_order": 1, "result": "AC", "execution_time": "3661 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    for i in range(len(x)):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD462AF89E301", "submission_order": 1, "result": "RE", "execution_time": "1192 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in len(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD462AF89E301", "submission_order": 2, "result": "RE", "execution_time": "1184 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD462AF89E301", "submission_order": 3, "result": "AC", "execution_time": "1781 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD46365CE04C1", "submission_order": 1, "result": "RE", "execution_time": "1688 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y[i])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD46365CE04C1", "submission_order": 2, "result": "AC", "execution_time": "1826 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD5F7040C4607", "submission_order": 1, "result": "AC", "execution_time": "1590 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD709580E2B3B", "submission_order": 1, "result": "AC", "execution_time": "1734 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD730F063333D", "submission_order": 1, "result": "AC", "execution_time": "1856 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD76C9A8AD9BE", "submission_order": 1, "result": "AC", "execution_time": "1733 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD835B88510F9", "submission_order": 1, "result": "WA", "execution_time": "926 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.mct([i for i in range(n)], n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD835B88510F9", "submission_order": 2, "result": "RE", "execution_time": "820 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n)\n    qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD835B88510F9", "submission_order": 3, "result": "AC", "execution_time": "2058 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD867A57B4CA6", "submission_order": 1, "result": "RE", "execution_time": "1099 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in n:qc.cx(i,n + 1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AD867A57B4CA6", "submission_order": 2, "result": "AC", "execution_time": "1879 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n \n    for i in range(n):\n      qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADAEC1EBF5E98", "submission_order": 1, "result": "AC", "execution_time": "2483 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADAEC1EBF5E98", "submission_order": 2, "result": "AC", "execution_time": "2483 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADC7D8F73C58E", "submission_order": 1, "result": "WA", "execution_time": "992 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(n,i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADC7D8F73C58E", "submission_order": 2, "result": "WA", "execution_time": "1080 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(0,i+1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADC7D8F73C58E", "submission_order": 3, "result": "WA", "execution_time": "1021 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(y,x[i])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADC7D8F73C58E", "submission_order": 4, "result": "AC", "execution_time": "2751 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADC94DE0A0B4B", "submission_order": 1, "result": "AC", "execution_time": "3589 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADE901F007DE8", "submission_order": 1, "result": "RE", "execution_time": "2150 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cnx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADE901F007DE8", "submission_order": 2, "result": "WA", "execution_time": "1690 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.mcx(x,y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADE901F007DE8", "submission_order": 3, "result": "WA", "execution_time": "1570 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x)\n    qc.mcx(x,y)\n    qc.x(x)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADE901F007DE8", "submission_order": 4, "result": "WA", "execution_time": "1561 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x)\n    qc.mcx(x,y)\n    qc.x(x)\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADE901F007DE8", "submission_order": 5, "result": "RE", "execution_time": "1443 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(n,y)\n   \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADE901F007DE8", "submission_order": 6, "result": "AC", "execution_time": "2208 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i,y)\n   \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADEA840AE1A28", "submission_order": 1, "result": "AC", "execution_time": "1759 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "ADF9DCF0E1981", "submission_order": 1, "result": "AC", "execution_time": "1787 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE070E42A4971", "submission_order": 1, "result": "AC", "execution_time": "2126 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE08180924F20", "submission_order": 1, "result": "RE", "execution_time": "2232 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(range(n-1), range(1,n))\n    qc.cx(x[n-1], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE08180924F20", "submission_order": 2, "result": "RE", "execution_time": "1047 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(range(n-1), range(1,n))\n    n = len(x)\n    qc.cx(x[n-1], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE08180924F20", "submission_order": 3, "result": "RE", "execution_time": "945 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    qc.cx(range(x[n-1]), range(x[1],x[n]))\n    qc.cx(x[n-1], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE08180924F20", "submission_order": 4, "result": "WA", "execution_time": "1039 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n-1):\n        qc.cx(x[i], x[i+1])\n    qc.cx(x[n-1], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE08180924F20", "submission_order": 5, "result": "AC", "execution_time": "1527 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE17FE6C008E8", "submission_order": 1, "result": "AC", "execution_time": "2160 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cnot(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 1, "result": "RE", "execution_time": "783 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.c(x)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 2, "result": "RE", "execution_time": "911 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.c(x)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 3, "result": "WA", "execution_time": "971 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x[n-1])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 4, "result": "RE", "execution_time": "840 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x[n])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 5, "result": "RE", "execution_time": "810 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x[n])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 6, "result": "RE", "execution_time": "882 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(x[range(n)])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 7, "result": "RE", "execution_time": "843 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(0, x[i])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 8, "result": "WA", "execution_time": "1244 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(y[0], x[i])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 9, "result": "WA", "execution_time": "1015 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(x[i], x[i+1])\n    qc.cx(x[n-1], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE23FCE913F83", "submission_order": 10, "result": "WA", "execution_time": "959 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0], y[0])\n    for i in range(1, n):\n        qc.cx(x[i-1], x[i])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE2E61A2D6632", "submission_order": 1, "result": "AC", "execution_time": "2427 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE3197A2B6624", "submission_order": 1, "result": "RE", "execution_time": "870 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx[x[i]]\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE3197A2B6624", "submission_order": 2, "result": "WA", "execution_time": "819 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)-1):\n        qc.cx(x[i+1],x[i])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE3197A2B6624", "submission_order": 3, "result": "AC", "execution_time": "1678 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE3B240C77F46", "submission_order": 1, "result": "AC", "execution_time": "1787 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    n = len(x)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE3C9C3A79996", "submission_order": 1, "result": "AC", "execution_time": "1521 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE5D856741CBA", "submission_order": 1, "result": "RE", "execution_time": "901 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n+1)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE5D856741CBA", "submission_order": 2, "result": "AC", "execution_time": "1604 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE601D1545A52", "submission_order": 1, "result": "AC", "execution_time": "2629 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE9044A27E6C7", "submission_order": 1, "result": "AC", "execution_time": "1757 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n=len(x)\n    for i in range(n):\n        qc.cx(x[i],y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE93D3E5655C0", "submission_order": 1, "result": "WA", "execution_time": "2005 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(n, i)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE93D3E5655C0", "submission_order": 2, "result": "AC", "execution_time": "2090 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AE9B5181F054E", "submission_order": 1, "result": "AC", "execution_time": "2407 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEA6D5D509F5E", "submission_order": 1, "result": "AC", "execution_time": "1466 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEB11EF22EBAA", "submission_order": 1, "result": "RE", "execution_time": "869 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    n = len(x)\n    for i in range(n-1):\n        qc.(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEB11EF22EBAA", "submission_order": 2, "result": "RE", "execution_time": "923 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    n = len(x)\n    for i in range(n-1):\n        qc.(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEB11EF22EBAA", "submission_order": 3, "result": "WA", "execution_time": "1045 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    n = len(x)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEB11EF22EBAA", "submission_order": 4, "result": "RE", "execution_time": "1023 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    n = len(x)\n    qc.cx(n-1,0)\n    for i in range(1, n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEB11EF22EBAA", "submission_order": 5, "result": "RE", "execution_time": "1061 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    n = len(x)\n    qc.cx(x[n-1],x[0])\n    for i in range(1, n-):\n        qc.cx(x[i], x[i+1])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEBD915DBF05B", "submission_order": 1, "result": "AC", "execution_time": "1463 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEC3BA78B055E", "submission_order": 1, "result": "WA", "execution_time": "1055 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    n = len(x)\n    for i in range(n - 1):\n        qc.cx(x[i], x[i + 1])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEC3BA78B055E", "submission_order": 2, "result": "WA", "execution_time": "1064 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    n = len(x)\n    for i in reversed(range(n - 1)):\n        qc.cx(x[i], x[i + 1])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEC3BA78B055E", "submission_order": 3, "result": "RE", "execution_time": "766 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    n = len(x)\n    for i in range(0, n, 2):\n        qc.cx(x[i], x[i + 1])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEC3BA78B055E", "submission_order": 4, "result": "WA", "execution_time": "989 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    n = len(x)\n    for i in range(0, n - 1):\n        qc.cx(x[i], x[n - 1])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEC3BA78B055E", "submission_order": 5, "result": "WA", "execution_time": "949 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    n = len(x)\n    for i in reversed(range(0, n - 1)):\n        qc.cx(x[i], x[n - 1])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEC3BA78B055E", "submission_order": 6, "result": "AC", "execution_time": "1890 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    n = len(x)\n    for i in range(0, n):\n        qc.cx(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AEEE147E502EC", "submission_order": 1, "result": "AC", "execution_time": "2415 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # B1と同様，cxでOK\n    for i in range(n):\n        qc.cx(i, n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF324E96AC5AA", "submission_order": 1, "result": "AC", "execution_time": "1732 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i],y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF33A48CC8D66", "submission_order": 1, "result": "RE", "execution_time": "900 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x(i),y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF33A48CC8D66", "submission_order": 2, "result": "RE", "execution_time": "1055 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(x(i),y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF33A48CC8D66", "submission_order": 3, "result": "RE", "execution_time": "880 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(x(i),y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF33A48CC8D66", "submission_order": 4, "result": "WA", "execution_time": "943 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF33A48CC8D66", "submission_order": 5, "result": "AC", "execution_time": "2593 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = len(x)\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF485D871760F", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n \n    for i in range(n):\n        qc.cx(x[i], y)\n \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF581517F532F", "submission_order": 1, "result": "AC", "execution_time": "1403 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cx(x[i],y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF659F7A2DD61", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n): \n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF659F7A2DD61", "submission_order": 2, "result": "AC", "execution_time": "2773 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n): \n        qc.cx(x[i],n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF888CBD9366D", "submission_order": 1, "result": "RE", "execution_time": "1136 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF888CBD9366D", "submission_order": 2, "result": "WA", "execution_time": "1185 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF888CBD9366D", "submission_order": 3, "result": "AC", "execution_time": "3944 ms", "memory": "290 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF9FA7CE35A50", "submission_order": 1, "result": "WA", "execution_time": "913 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    if n % 2 == 0:\n        qc.x(n)\n    for i in range(2**n):\n        bit = 0\n        for j in range(n):\n            if (i / 2**j) % 2 == 1:\n                bit += 1\n        if bit % 2 == 1:\n            continue\n        for j in range(n):\n            if (i / 2**j) % 2 == 1:\n                qc.x(j)\n        qc.mcx(x, y)\n        for j in range(n):\n            if (i / 2**j) % 2 == 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF9FA7CE35A50", "submission_order": 2, "result": "WA", "execution_time": "977 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    if n % 2 == 0:\n        qc.x(y)\n    for i in range(2**n):\n        bit = 0\n        for j in range(n):\n            if (i / (2**j)) % 2 == 1:\n                bit += 1\n        if bit % 2 == 1:\n            continue\n        for j in range(n):\n            if (i / (2**j)) % 2 == 1:\n                qc.x(x[j])\n        qc.mcx(x, y)\n        for j in range(n):\n            if (i / (2**j)) % 2 == 1:\n                qc.x(x[j])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AF9FA7CE35A50", "submission_order": 3, "result": "AC", "execution_time": "1911 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    if n % 2 == 0:\n        qc.x(y)\n    for i in range(2**n):\n        bit = 0\n        for j in range(n):\n            if (i // (2**j)) % 2 == 1:\n                bit += 1\n        if bit % 2 == 1:\n            continue\n        for j in range(n):\n            if (i // (2**j)) % 2 == 1:\n                qc.x(x[j])\n        qc.mcx(x, y)\n        for j in range(n):\n            if (i // (2**j)) % 2 == 1:\n                qc.x(x[j])\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AFB14EB1E2E66", "submission_order": 1, "result": "AC", "execution_time": "1689 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AFB7F3E0D75E7", "submission_order": 1, "result": "AC", "execution_time": "1619 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(0, n):\n        qc.cx(x[i], y)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AFBEAFC2F637D", "submission_order": 1, "result": "AC", "execution_time": "1277 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Apply CNOT gates to implement the oracle\n    for i in range(n):\n        qc.cx(x[i], y[0])\n    \n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AFCB550AEFEAB", "submission_order": 1, "result": "AC", "execution_time": "1647 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AFCFB8E3944E7", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(x[i], y[0])\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AFD8BDC0171F0", "submission_order": 1, "result": "AC", "execution_time": "2124 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n=len(x)\n    for i in range(n):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AFDA57F998E97", "submission_order": 1, "result": "AC", "execution_time": "2420 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.cx(x[i], y)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_B2", "user": "AFDFB73E5A953", "submission_order": 1, "result": "AC", "execution_time": "2652 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)  # n量子ビットと1量子ビットを作成\n    qc = QuantumCircuit(x, y)  # 量子回路を作成\n\n    # オラクルの実装:\n    for i in range(n):\n        qc.cx(x[i], y[0])  # xの各ビットを制御ビットとして、yに対してCNOTゲートを適用\n\n    return qc\n'''"}
{"problem": "QPC001_B2", "user": "AFF4B02CDE629", "submission_order": 1, "result": "AC", "execution_time": "2553 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(len(x)):\n        qc.cx(x[i],y)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0384690392A6", "submission_order": 1, "result": "RE", "execution_time": "864 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(2*pi,i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0384690392A6", "submission_order": 2, "result": "RE", "execution_time": "982 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(pi,i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A040B44B2566B", "submission_order": 1, "result": "RE", "execution_time": "2619 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        #check if ith is 0\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n        #if everything is 1, multiply by -1\n        qc.append(ZGate().control(n-1), range(n))\n\n        #Put it back\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A040B44B2566B", "submission_order": 2, "result": "AC", "execution_time": "2342 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        #check if ith is 0\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n        if n == 1:\n            qc.z(0)\n        else:\n            #if everything is 1, multiply by -1\n            qc.append(ZGate().control(n-1), range(n))\n\n        #Put it back\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0474B1D26CF7", "submission_order": 1, "result": "RE", "execution_time": "1579 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i&(1<<j)!=0:\n                continue\n            qc.x(j)\n\n        qc.append(ZGate().control(n-1),range(n))\n        \n        for j in range(n):\n            if i&(1<<j)!=0:\n                continue\n            qc.x(j)\n            \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0474B1D26CF7", "submission_order": 2, "result": "AC", "execution_time": "1871 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i&(1<<j)!=0:\n                continue\n            qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1),range(n))\n        else:\n            qc.z(0)\n\n        for j in range(n):\n            if i&(1<<j)!=0:\n                continue\n            qc.x(j)\n            \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A04A7735EFDEE", "submission_order": 1, "result": "RE", "execution_time": "995 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    mask = 2 ** (n - 1) - 1\n\n    for l in range(L):\n        qc.append(ZGate().control(n-1, None, l & mask), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A04A7735EFDEE", "submission_order": 2, "result": "WA", "execution_time": "1527 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    mask = 2 ** (n - 1) - 1\n\n    for l in range(L):\n        qc.append(ZGate().control(n-1, None, l & mask), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A04A7735EFDEE", "submission_order": 3, "result": "TLE", "execution_time": "3000 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    mask = 2 ** (n - 1) - 1\n\n    for l in range(L):\n        if l >> (n - 1) == 0:\n            qc.x(n-1)\n        qc.append(ZGate().control(n-1, None, l & mask), range(n))\n        if l >> (n - 1) == 0:\n            qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A04A7735EFDEE", "submission_order": 4, "result": "AC", "execution_time": "2274 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    mask = 2 ** (n - 1) - 1\n\n    qc.x(n-1)\n\n    for l in range(L):\n        if l >> (n - 1) != 0:\n            qc.x(n-1)\n        qc.append(ZGate().control(n-1, None, l & mask), range(n))\n        if l >> (n - 1) != 0:\n            qc.x(n-1)\n\n    qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A05DC2466D892", "submission_order": 1, "result": "WA", "execution_time": "1944 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = [(L>>i)for i in range(n)]\n    if l[n-1]==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if l[i]==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            for j in range(i+1,n):\n                qc.cz(i,j)\n            qc.z(i)\n            qc.x(i)\n    for i in range(n):\n        if l[i]==0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A05DC2466D892", "submission_order": 2, "result": "RE", "execution_time": "1971 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for k in range(L):\n        for i in range(n):\n            if (k>>i)&1 == 0:\n                qc.x(i)\n        qc.append(ZGate().control(n-1),range(n))\n        for i in range(n):\n            if (k>>i)&1 == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A05DC2466D892", "submission_order": 3, "result": "AC", "execution_time": "2140 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for k in range(L):\n        for i in range(n):\n            if (k>>i)&1 == 0:\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for i in range(n):\n            if (k>>i)&1 == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 1, "result": "RE", "execution_time": "833 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(Zgate().control(n-1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n-1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 3, "result": "RE", "execution_time": "937 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n-1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 4, "result": "RE", "execution_time": "925 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.x(i)\n    \n    target_qubit = n-1 \n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n        if control_qubits == [target_qubit]:\n            break\n        cz_gate = ZGate().control(len(control_qubits))\n        qc.append(cz_gate, control_qubits+[target_qubit])\n        \n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 5, "result": "RE", "execution_time": "879 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    target_qubit = n-1 \n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n        if control_qubits == [target_qubit]:\n            break\n        cz_gate = ZGate().control(len(control_qubits))\n        qc.append(cz_gate, control_qubits+[target_qubit])\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 6, "result": "RE", "execution_time": "1256 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        qc.x(i)\n    \n    target_qubit = n-1 \n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n        if control_qubits == [target_qubit]:\n            break\n        cz_gate = ZGate().control(len(control_qubits))\n        qc.append(cz_gate, control_qubits+[target_qubit])\n    \n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 7, "result": "RE", "execution_time": "952 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.x(i)\n    \n    target_qubit = n-1 \n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string]\n        control_qubits = []\n        counter = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n        if control_qubits == [target_qubit]:\n            break\n        cz_gate = ZGate().control(len(control_qubits))\n        qc.append(cz_gate, control_qubits+[target_qubit])\n    \n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 8, "result": "RE", "execution_time": "1135 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    target_qubit = n-1 \n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n        if control_qubits == [target_qubit]:\n            break\n        cz_gate = ZGate().control(len(control_qubits))\n        qc.append(cz_gate, control_qubits+[target_qubit])\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 9, "result": "RE", "execution_time": "889 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    target_qubit = n-1 \n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-]]\n        control_qubits = []\n        counter = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n            if control_qubits == [target_qubit]:\n                break\n        cz_gate = ZGate().control(len(control_qubits))\n        qc.append(cz_gate, control_qubits+[target_qubit])\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 10, "result": "RE", "execution_time": "886 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    target_qubit = n-1 \n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n            if control_qubits == [target_qubit]:\n                break\n        cz_gate = ZGate().control(len(control_qubits))\n        qc.append(cz_gate, control_qubits+[target_qubit])\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 11, "result": "RE", "execution_time": "980 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    target_qubit = n-1\n    for i in range(n):\n        qc.h(i)\n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        flag = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n            if counter == target_qubit:\n                flag = 1\n                break\n        if flag == 0:\n            cz_gate = ZGate().control(len(control_qubits))\n            qc.append(cz_gate, control_qubits+[target_qubit])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 12, "result": "RE", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    target_qubit = n-1\n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        flag = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n            if counter == target_qubit:\n                flag = 1\n                break\n        if flag == 0:\n            cz_gate = ZGate().control(len(control_qubits))\n            qc.append(cz_gate, control_qubits+[target_qubit])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 13, "result": "RE", "execution_time": "1089 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    target_qubit = n-1\n    control_history = []\n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        flag = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n            if counter == target_qubit:\n                break\n        if [target_qubit]!=control_qubits and len(control_qubits)!=0 and not(control_qubits in control_history):\n            print(control_qubits+[target_qubit])\n            cz_gate = ZGate().control(len(control_qubits))\n            qc.append(cz_gate, control_qubits+[target_qubit])\n            control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 14, "result": "RE", "execution_time": "1087 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    target_qubit = n-1\n    control_history = []\n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        flag = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n            if counter == target_qubit:\n                break\n        if [target_qubit]!=control_qubits and len(control_qubits)!=0 and not(control_qubits in control_history):\n            print(control_qubits+[target_qubit])\n            cz_gate = ZGate().control(len(control_qubits))\n            qc.append(cz_gate, control_qubits+[target_qubit])\n            control_history.append(control_qubits)\n    qc.x(target_qubit)\n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        flag = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n            if counter == target_qubit:\n                break\n        if [target_qubit]!=control_qubits and len(control_qubits)!=0 and not(control_qubits in control_history):\n            print(control_qubits+[target_qubit])\n            cz_gate = ZGate().control(len(control_qubits))\n            qc.append(cz_gate, control_qubits+[target_qubit])\n            control_history.append(control_qubits)\n    qc.x(target_qubit)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 15, "result": "RE", "execution_time": "1041 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    target_qubit = n-1\n    control_history = []\n    for num in range(L,pow(2,n)+1):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        flag = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n        if [target_qubit]!=control_qubits and len(control_qubits)!=0 and not(control_qubits in control_history):\n            print(control_qubits)\n            cz_gate = ZGate().control(len(control_qubits))\n            qc.append(cz_gate, control_qubits)\n            control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 16, "result": "WA", "execution_time": "1101 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    control_history = []\n    for num in range(L,pow(2,n)):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        flag = 0\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n        if not(control_qubits in control_history):\n            print(control_qubits)\n            if len(control_qubits) -1 == 0:\n                qc.z(control_qubits[0])\n            else:\n                cz_gate = ZGate().control(len(control_qubits)-1)\n                qc.append(cz_gate, control_qubits)\n            control_history.append(control_qubits)\n\n            \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 17, "result": "RE", "execution_time": "889 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    control_history = []\n    for num in range(L,pow(2,n)):\n        binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n        binary_list = [int(bit) for bit in binary_string[::-1]]\n        control_qubits = []\n        counter = 0\n        flag = 0\n        all_qubits = []\n        for i in range(n):\n            all_qubits.append(i)\n\n        for b in binary_list:\n            if b==1:\n                control_qubits.append(counter)\n                counter+=1\n            else:\n                counter+=1\n        if not(control_qubits in control_history):\n            print(control_qubits)\n            if len(control_qubits) -1 != 0:\n                for i in range(n):\n                    if not i in control_qubits:\n                        qc.x(i)\n                cz_gate = ZGate().control(len(all_qubits)-1)\n                qc.append(cz_gate, all_qubits)\n                for i in range(n):\n                    if not i in control_qubits:\n                        qc.x(i)\n            else:\n                for i in range(n):\n                    if not i in control_qubits:\n                        qc.x(i)\n                cz_gate = ZGate().control(len(all_qubits)-1)\n                qc.append(cz_gate, all_qubits)\n                for i in range(n):\n                    if not i in control_qubits:\n                        qc.x(i)\n            control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 18, "result": "RE", "execution_time": "1257 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1:\n        if L==1:\n            qc.z(i)\n    else:\n        control_history = []\n        for num in range(L,pow(2,n)):\n            binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n            binary_list = [int(bit) for bit in binary_string[::-1]]\n            control_qubits = []\n            counter = 0\n            flag = 0\n            all_qubits = []\n            for i in range(n):\n                all_qubits.append(i)\n\n            for b in binary_list:\n                if b==1:\n                    control_qubits.append(counter)\n                    counter+=1\n                else:\n                    counter+=1\n            if not(control_qubits in control_history):\n                print(control_qubits)\n                if len(control_qubits) -1 != 0:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                else:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 19, "result": "RE", "execution_time": "984 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1 and L==1\n            qc.z(i)\n    else:\n        control_history = []\n        for num in range(L,pow(2,n)):\n            binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n            binary_list = [int(bit) for bit in binary_string[::-1]]\n            control_qubits = []\n            counter = 0\n            flag = 0\n            all_qubits = []\n            for i in range(n):\n                all_qubits.append(i)\n\n            for b in binary_list:\n                if b==1:\n                    control_qubits.append(counter)\n                    counter+=1\n                else:\n                    counter+=1\n            if not(control_qubits in control_history):\n                print(control_qubits)\n                if len(control_qubits) -1 != 0:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                else:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 20, "result": "RE", "execution_time": "975 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1 and L==1\n            qc.z(0)\n    else:\n        control_history = []\n        for num in range(L,pow(2,n)):\n            binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n            binary_list = [int(bit) for bit in binary_string[::-1]]\n            control_qubits = []\n            counter = 0\n            flag = 0\n            all_qubits = []\n            for i in range(n):\n                all_qubits.append(i)\n\n            for b in binary_list:\n                if b==1:\n                    control_qubits.append(counter)\n                    counter+=1\n                else:\n                    counter+=1\n            if not(control_qubits in control_history):\n                print(control_qubits)\n                if len(control_qubits) -1 != 0:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                else:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A064987F64B27", "submission_order": 21, "result": "AC", "execution_time": "2074 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1 and L==1:\n            qc.z(0)\n    else:\n        control_history = []\n        for num in range(L,pow(2,n)):\n            binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n            binary_list = [int(bit) for bit in binary_string[::-1]]\n            control_qubits = []\n            counter = 0\n            flag = 0\n            all_qubits = []\n            for i in range(n):\n                all_qubits.append(i)\n\n            for b in binary_list:\n                if b==1:\n                    control_qubits.append(counter)\n                    counter+=1\n                else:\n                    counter+=1\n            if not(control_qubits in control_history):\n                print(control_qubits)\n                if len(control_qubits) -1 != 0:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                else:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 1, "result": "RE", "execution_time": "986 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=lst(range(n))\n    l.remote(L)\n    qc.h(L)\n    qc.mcx(l,L)\n    qc.h(L)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 2, "result": "RE", "execution_time": "888 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=list(range(n))\n    l.remove(L)\n    qc.h(L)\n    qc.mcx(l,L)\n    qc.h(L)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 3, "result": "RE", "execution_time": "905 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=list(range(n))\n    t=L//2\n    j=L%2\n    l.remove(t)\n    qc.h(t)\n    qc.mcx(l,t)\n    qc.h(t)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 4, "result": "RE", "execution_time": "910 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=list(range(n))\n    t=L//2\n    j=L%2\n    l.remove(t)\n    qc.h(t)\n    qc.mcx(l,t)\n    qc.h(t)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 5, "result": "RE", "execution_time": "950 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 6, "result": "RE", "execution_time": "830 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    if j == 1 : qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    if j == 1 : qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 7, "result": "RE", "execution_time": "946 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    if j == 1 : qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    if j == 1 : qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 8, "result": "RE", "execution_time": "1055 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    if j == 0 : qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    if j == 0 : qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 9, "result": "RE", "execution_time": "1225 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    if j == 0 : qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    if j == 0 : qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 10, "result": "RE", "execution_time": "885 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 11, "result": "RE", "execution_time": "838 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 0: return qc.z(0)\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 12, "result": "RE", "execution_time": "870 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1: return qc.z(0)\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 13, "result": "RE", "execution_time": "1109 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 1: return qc.z(0)\n        else: return qc.x(0).z(0).x(0)\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 14, "result": "RE", "execution_time": "810 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 1: return qc.z(0)\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            return qc\n    t=L//2\n    j=L%2\n    l=list(range(n))\n    ll=list(range(n))\n    ll.remove(t)\n    qc.x(l)\n    qc.h(t)\n    qc.mcx(ll,t)\n    qc.h(t)\n    qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A09B92AA80D26", "submission_order": 15, "result": "RE", "execution_time": "798 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n    else:\n        t=L//2\n        j=L%2\n        l=list(range(n))\n        ll=list(range(n))\n        ll.remove(t)\n        qc.x(l)\n        qc.h(t)\n        qc.mcx(ll,t)\n        qc.h(t)\n        qc.x(l)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0A9A64649086", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0B410C11FB2F", "submission_order": 1, "result": "WA", "execution_time": "1168 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from qiskit.circuit.library import ZGate\n    for i in range(L):\n        for j in range(n):\n            if ((L>>j)&1)==0:\n                qc.x(j)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if ((L>>j)&1)==0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0B410C11FB2F", "submission_order": 2, "result": "AC", "execution_time": "2894 ms", "memory": "97 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from qiskit.circuit.library import ZGate\n    for i in range(L):\n        for j in range(n):\n            if ((i>>j)&1)==0:\n                qc.x(j)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if ((i>>j)&1)==0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0D2B3A14CE18", "submission_order": 1, "result": "UGE", "execution_time": "858 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.diagonal([-1 if i < L else 1 for i in range(2**n)], list(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E407728960F", "submission_order": 1, "result": "RE", "execution_time": "878 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # 各計算基底状態に対してフェイズ反転ゲートを適用\n    for i in range(2**n):\n        qc.z(n)  # nビット目に対してフェイズ反転ゲートを適用\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 1, "result": "RE", "execution_time": "941 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(ZGate().control(n - 1), range(L))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 2, "result": "RE", "execution_time": "1089 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        for j in range(n):\n            if not i >> j & 1:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not i >> j & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import *\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        for j in range(n):\n            if not i >> j & 1:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not i >> j & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 4, "result": "RE", "execution_time": "992 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        for j in range(n):\n            if not i >> j & 1:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not i >> j & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 5, "result": "RE", "execution_time": "855 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        qc.append(ZGate().control(i), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 6, "result": "RE", "execution_time": "824 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        for j in range(n):\n            if not i >> j & 1:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not i >> j & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 7, "result": "RE", "execution_time": "1298 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(min(1<<(n-1),L)):\n        qc.append(ZGate().control(n-1,ctrl_state=i), range(n))\n    qc.x(n-1)\n    if L > (1<<(n-1)):\n        for i in range(L-(1<<(n-1))):\n            qc.append(ZGate().control(n-1,ctrl_state=i), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 8, "result": "RE", "execution_time": "1017 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(min(1<<(n-1),L)):\n        qc.append(ZGate().control(n-1,ctrl_state=i), range(n))\n    qc.x(n-1)\n    if L > (1<<(n-1)):\n        for i in range(L-(1<<(n-1))):\n            qc.append(ZGate().control(n-1,ctrl_state=i), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 9, "result": "WA", "execution_time": "910 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\ndef solve(n, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        if L == 1:\n            qc.z(0)\n            qc.x(0)\n        else:\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n    else:\n        for i in range(min(1<<(n-1),L)):\n            qc.append(ZGate().control(n-1,ctrl_state=i), range(n))\n        qc.x(n-1)\n        if L > (1<<(n-1)):\n            for i in range(L-(1<<(n-1))):\n                qc.append(ZGate().control(n-1,ctrl_state=i), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0E7B84F76137", "submission_order": 10, "result": "WA", "execution_time": "1208 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\ndef solve(n, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        if L == 1:\n            qc.z(0)\n            qc.x(0)\n        else:\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n    else:\n        for i in range(min(1<<(n-1),L)):\n            qc.append(ZGate().control(n-1,ctrl_state=i), range(n))\n        if L > (1<<(n-1)):\n            qc.x(n-1)\n            for i in range(L-(1<<(n-1))):\n                qc.append(ZGate().control(n-1,ctrl_state=i), range(n))\n            qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0F0F7C252D05", "submission_order": 1, "result": "RE", "execution_time": "820 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(ZGate().control(n-1),range(n))\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A0F1695B29CEC", "submission_order": 1, "result": "AC", "execution_time": "2132 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    K = L - 1\n\n    xgates = []\n    for i in range(n - 1, -1, -1):\n        if (K >> i) & 1:\n            continue\n\n        if i < n - 1:\n            qc.mcp(pi, list(range(i + 1, n)), i)\n        else:\n            qc.z(i)\n\n        xgates.append(i)\n        qc.x(i)\n\n    for i in xgates:\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 1, "result": "RE", "execution_time": "939 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(XGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 2, "result": "RE", "execution_time": "845 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(CXGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 3, "result": "RE", "execution_time": "794 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(XGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 4, "result": "RE", "execution_time": "849 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 5, "result": "RE", "execution_time": "1109 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport qiskit\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate().control(n - 1)\n    qc.append(gate, range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 7, "result": "RE", "execution_time": "1244 ms", "memory": "91 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\nfrom qiskit.circuit.library import CXGate\nfrom qiskit.circuit.library import MCPhaseGate\nfrom qiskit.circuit.library import MCMT\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate().control(n - 1)\n    qc.append(gate, range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 8, "result": "RE", "execution_time": "1190 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate().control(n - 1)\n#    qc.append(gate, range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 9, "result": "RE", "execution_time": "1214 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate()\n    qc.append(gate.control(n-1), range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 10, "result": "RE", "execution_time": "1120 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    if(L <= 2**n):\n        qc = QuantumCircuit(n)\n        gate = ZGate()\n        qc.append(gate.control(n-1), range(n))\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 11, "result": "WA", "execution_time": "831 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate()\n#    qc.append(gate.control(n-1), range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 12, "result": "RE", "execution_time": "948 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n,n)\n    gate = ZGate()\n    qc.append(gate.control(n-1), range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 13, "result": "RE", "execution_time": "899 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate()\n    qc.append(gate.control(n-1), list(range(n)))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 14, "result": "RE", "execution_time": "878 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = CZGate()\n    qc.append(gate.control(n-1), list(range(n)))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 15, "result": "RE", "execution_time": "1031 ms", "memory": "87 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = CZGate()\n    qc.append(gate.control(n-1), range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 16, "result": "RE", "execution_time": "1151 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    ccz(qc,n)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n\ndef ccz(qc, n):\n    gate = CZGate()\n    qc.append(gate.control(n-1), range(n))\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 17, "result": "RE", "execution_time": "719 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    ccz(qc,n)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n\ndef ccz(qc, n):\n    gate = ZGate()\n    qc.append(gate.control(n-1), range(n))\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 18, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate()\n    qc.append(gate.control(n-1), range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 19, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit.circuit.library import ZGate\nfrom qiskit.circuit.library.standard_gates import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate()\n    qc.append(gate.control(n-1), range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 20, "result": "RE", "execution_time": "1138 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate().control(n-1)\n    qc.append(gate, range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 21, "result": "RE", "execution_time": "747 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate().control(n-1)\n    lt=list(range(n))\n    qc.append(gate, lt)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 22, "result": "RE", "execution_time": "1113 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate().control(n-1)\n    lt=list(range(n))\n    qc.append(gate, lt)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A10E4F643C1BC", "submission_order": 23, "result": "RE", "execution_time": "1193 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n,n)\n    gate = ZGate().control(n-1)\n    lt=list(range(n))\n    qc.append(gate, lt)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A12859DD1283C", "submission_order": 1, "result": "QLE", "execution_time": "911 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2**n)\n\n    for i in range(L):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A12859DD1283C", "submission_order": 2, "result": "RE", "execution_time": "1028 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2**n)\n\n    from qiskit.circuit.library import ZGate\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A12859DD1283C", "submission_order": 3, "result": "RE", "execution_time": "877 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2**n)\n\n    from qiskit.circuit.library import ZGate\n    qc.append(ZGate().control(n - 1), range(L))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A12859DD1283C", "submission_order": 4, "result": "RE", "execution_time": "1079 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2**n)\n\n    from qiskit.circuit.library import ZGate\n    qc.append(ZGate().control(L - 1), range(L))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A13229657D7E6", "submission_order": 1, "result": "RE", "execution_time": "1215 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for l in range(L):\n        # Create a list of target qubits that need to be flipped\n        control_bits = []\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)  # Apply X gate to flip the qubit\n            control_bits.append(i)\n        \n        # Apply controlled-Z gate\n        qc.mcx(control_bits[:-1], control_bits[-1])  # multi-controlled X (equivalent to Z in phase kickback)\n        \n        # Revert the X gate\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A139750AA057F", "submission_order": 1, "result": "RE", "execution_time": "1079 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A139750AA057F", "submission_order": 2, "result": "RE", "execution_time": "1536 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A139750AA057F", "submission_order": 3, "result": "RE", "execution_time": "1460 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n        \n        if n == 1:\n            qc.z(1)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A139750AA057F", "submission_order": 4, "result": "AC", "execution_time": "2226 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n        \n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A15C7AD9354B0", "submission_order": 1, "result": "RE", "execution_time": "1115 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \"\"\"\n    binary_L_minus_1 = format(L - 1, '0' + str(n) + 'b')[::-1]\n    for qubit in range(n):\n        if binary_L_minus_1[qubit] == '0':\n            qc.x(qubit)\n    \n    qc.h(n-1)\n    qc.mcx(list(range(n-1)),n-1)\n    qc.h(n-1)\n\n    for qubit in range(n):\n        if binary_L_minus_1[qubit] == '0':\n            qc.x(qubit)\n    \"\"\"\n    for l_little in range(L):\n        binary_L_minus_1 = format(l_little, '0' + str(n) + 'b')[::-1]\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                qc.x(qubit)\n        \n        qc.h(n-1)\n        qc.mcx(list(range(n-1)),n-1)\n        qc.h(n-1)\n\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A15C7AD9354B0", "submission_order": 2, "result": "AC", "execution_time": "2167 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \"\"\"\n    binary_L_minus_1 = format(L - 1, '0' + str(n) + 'b')[::-1]\n    for qubit in range(n):\n        if binary_L_minus_1[qubit] == '0':\n            qc.x(qubit)\n    \n    qc.h(n-1)\n    qc.mcx(list(range(n-1)),n-1)\n    qc.h(n-1)\n\n    for qubit in range(n):\n        if binary_L_minus_1[qubit] == '0':\n            qc.x(qubit)\n    \"\"\"\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L == 2:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n        return qc\n    for l_little in range(L):\n        binary_L_minus_1 = format(l_little, '0' + str(n) + 'b')[::-1]\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                qc.x(qubit)\n        \n        qc.h(n-1)\n        qc.mcx(list(range(n-1)),n-1)\n        qc.h(n-1)\n\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 1, "result": "RE", "execution_time": "804 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate.control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 2, "result": "RE", "execution_time": "1084 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 3, "result": "RE", "execution_time": "890 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n - 1))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 4, "result": "RE", "execution_time": "936 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n - 1))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 5, "result": "RE", "execution_time": "883 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(HGate(), range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 6, "result": "RE", "execution_time": "965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 7, "result": "RE", "execution_time": "1165 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 8, "result": "RE", "execution_time": "936 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(L - 1), range(L))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A16B9D4803ECF", "submission_order": 9, "result": "RE", "execution_time": "797 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(L))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1838949724FE", "submission_order": 1, "result": "RE", "execution_time": "1003 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):  # このループが一番のポイント\n            if ((i >> j) & 1)==0:  # 順に右にシフトさせ最下位bitのチェックを行う\n                qc.x(j)  # フラグが立っていたら j にxgate\n\n        # MCZ start\n        qc.h(n - 1)\n        qc.append(MCXGate(n - 1), list(range(n)))\n        qc.h(n - 1)\n        # MCZ end\n\n        for j in range(n):  # このループが一番のポイント\n            if ((i >> j) & 1)==0:  # 順に右にシフトさせ最下位bitのチェックを行う\n                qc.x(j)  # フラグが立っていたら j にxgate\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1838949724FE", "submission_order": 2, "result": "RE", "execution_time": "1094 ms", "memory": "91 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):  # このループが一番のポイント\n            if ((i >> j) & 1)==0:  # 順に右にシフトさせ最下位bitのチェックを行う\n                qc.x(j)  # フラグが立っていたら j にxgate\n\n        # MCZ start\n        qc.h(n - 1)\n        qc.append(MCXGate(n - 1), list(range(n)))\n        qc.h(n - 1)\n        # MCZ end\n\n        for j in range(n):  # このループが一番のポイント\n            if ((i >> j) & 1)==0:  # 順に右にシフトさせ最下位bitのチェックを行う\n                qc.x(j)  # フラグが立っていたら j にxgate\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1838949724FE", "submission_order": 3, "result": "AC", "execution_time": "2019 ms", "memory": "91 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    if n == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n    else:\n        for i in range(L):\n            for j in range(n):  # このループが一番のポイント\n                if ((i >> j) & 1)==0:  # 順に右にシフトさせ最下位bitのチェックを行う\n                    qc.x(j)  # フラグが立っていたら j にxgate\n\n            # MCZ start\n            qc.h(n - 1)\n            qc.append(MCXGate(n - 1), list(range(n)))\n            qc.h(n - 1)\n            # MCZ end\n\n            for j in range(n):  # このループが一番のポイント\n                if ((i >> j) & 1)==0:  # 順に右にシフトさせ最下位bitのチェックを行う\n                    qc.x(j)  # フラグが立っていたら j にxgate\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1B26B52B204E", "submission_order": 1, "result": "AC", "execution_time": "2238 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (L & (1 << i)) == 0:\n            qc.x(i)\n    for i in range(n):\n        if (L & (1 << i)) != 0:\n            qc.x(i)\n            if i + 1 < n:\n                qc.append(ZGate().control(n - i - 1), range(i, n))\n            else:\n                qc.z(i)\n            qc.x(i)\n    for i in range(n):\n        if (L & (1 << i)) == 0:\n            qc.x(i)\n    # print(qc)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n\n#     qc = solve(3, 5)\n#     print(Statevector(qc))\n#     sv = Statevector.from_label('+++')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC001_B3", "user": "A1B30F589840C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(ZGate().control(L - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1DC3719F49B2", "submission_order": 1, "result": "RE", "execution_time": "2702 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t = QuantumRegister(1, \"t\")\n    qc.add_bits(t)\n\n    qc.x(range(n))\n    qc.append(AND(n), [0, 1, t])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1DC3719F49B2", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import AND, RXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t = QuantumRegister(1, \"t\")\n    qc.add_bits(t)\n\n    qc.x(range(n))\n    qc.append(AND(n), [0, 1, t])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1DC3719F49B2", "submission_order": 3, "result": "RE", "execution_time": "2567 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t = QuantumRegister(1, \"t\")\n    qc.add_bits(t)\n\n    for i in range(L):\n        # i to binary bits\n        bits = [(i >> j) & 1 for j in range(n)]\n\n        # Apply gates based on bits\n        zero_indices = [j for j, bit in enumerate(bits) if bit == 0]\n        qc.x(zero_indices)\n        qc.append(XGate().control(n), [*range(n), t[0]])\n        qc.crx(math.pi * 2.0, t, 0)\n        qc.append(XGate().control(n), [*range(n), t[0]])\n        qc.x(zero_indices)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1DC3719F49B2", "submission_order": 4, "result": "RE", "execution_time": "1867 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t = QuantumRegister(1, \"t\")\n    qc.add_bits(t)\n\n    for i in range(L):\n        # i to binary bits\n        bits = [(i >> j) & 1 for j in range(n)]\n\n        # Apply gates based on bits\n        zero_indices = [j for j, bit in enumerate(bits) if bit == 0]\n        qc.x(zero_indices)\n        qc.append(XGate().control(n), [*range(n), t[0]])\n        qc.crx(math.pi * 2.0, t, 0)\n        qc.append(XGate().control(n), [*range(n), t[0]])\n        qc.x(zero_indices)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1DC3719F49B2", "submission_order": 5, "result": "RE", "execution_time": "2110 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t = QuantumRegister(1, \"t\")\n    qc.add_bits(t)\n\n    for i in range(L):\n        # i to binary bits\n        bits = [(i >> j) & 1 for j in range(n)]\n\n        # Apply gates based on bits\n        zero_indices = [j for j, bit in enumerate(bits) if bit == 0]\n        qc.x(zero_indices)\n        qc.append(XGate().control(n), [*range(n), t[0]])\n        qc.crx(math.pi * 2.0, t, 0)\n        qc.append(XGate().control(n), [*range(n), t[0]])\n        qc.x(zero_indices)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1DC3719F49B2", "submission_order": 6, "result": "AC", "execution_time": "2366 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t = QuantumRegister(1, \"t\")\n    qc.add_bits(t)\n\n    for i in range(L):\n        # i to binary bits\n        bits = [(i >> j) & 1 for j in range(n)]\n\n        # Apply gates based on bits\n        zero_indices = [j for j, bit in enumerate(bits) if bit == 0]\n        if len(zero_indices) > 0:\n            qc.x(zero_indices)\n        qc.append(XGate().control(n), [*range(n), t[0]])\n        qc.crx(math.pi * 2.0, t, 0)\n        qc.append(XGate().control(n), [*range(n), t[0]])\n        if len(zero_indices) > 0:\n            qc.x(zero_indices)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A1E766923D4CD", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # vec = np.zeros(1<<n)\n    # vec[5] = 1\n    # qc.initialize(vec) \n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i & (1<<j)) == 0:\n                qc.x(j)\n        qc.append(ZGate().control(n-1), range(0, n))\n        for j in range(n):\n            if (i & (1<<j)) == 0:\n                qc.x(j)\n    return qc\n\nqc = solve(3,5)\nprint(qc)\nprint(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC001_B3", "user": "A1E766923D4CD", "submission_order": 2, "result": "RE", "execution_time": "1621 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\n#from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # vec = np.zeros(1<<n)\n    # vec[5] = 1\n    # qc.initialize(vec) \n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i & (1<<j)) == 0:\n                qc.x(j)\n        qc.append(ZGate().control(n-1), range(0, n))\n        for j in range(n):\n            if (i & (1<<j)) == 0:\n                qc.x(j)\n    return qc\n\nqc = solve(3,5)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC001_B3", "user": "A1E766923D4CD", "submission_order": 3, "result": "AC", "execution_time": "2170 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\n#from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # vec = np.zeros(1<<n)\n    # vec[5] = 1\n    # qc.initialize(vec) \n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i & (1<<j)) == 0:\n                qc.x(j)\n        if n>=2 :\n            qc.append(ZGate().control(n-1), range(0, n))\n        else:\n            qc.z(0)\n        for j in range(n):\n            if (i & (1<<j)) == 0:\n                qc.x(j)\n    return qc\n\nqc = solve(3,5)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC001_B3", "user": "A239BD32ECEBC", "submission_order": 1, "result": "RE", "execution_time": "822 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in reversed(range(n)):\n        if ((L >> i) % 2 == 1):\n            if (i == n - 1):\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n - 1 - i), reversed(range(i, n)))\n                qc.x(i)\n        else:\n            qc.x(i)\n            ll.append(i)\n    for i in ll:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A239BD32ECEBC", "submission_order": 2, "result": "WA", "execution_time": "892 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in reversed(range(n)):\n        if ((L >> i) % 2 == 1):\n            if (i == n - 1):\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n - 1 - i), reversed(range(i, n)))\n                qc.x(i)\n        else:\n            qc.x(i)\n            ll.append(i)\n    for i in ll:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A239BD32ECEBC", "submission_order": 3, "result": "WA", "execution_time": "1196 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in range(n):\n        if ((L >> (n - i - 1)) & 1):\n            if (i == 0):\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(i), range(i + 1))\n                qc.x(i)\n        else:\n            # qc.x(i)\n            ll.append(i)\n    for i in ll:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A239BD32ECEBC", "submission_order": 4, "result": "WA", "execution_time": "1027 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in range(n):\n        if ((L >> (n - i - 1)) & 1):\n            if (i == 0):\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(i), range(i + 1))\n                qc.x(i)\n        else:\n            # qc.x(i)\n            ll.append(i)\n    for i in ll:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A239BD32ECEBC", "submission_order": 5, "result": "WA", "execution_time": "996 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in range(n):\n        if ((L >> i) & 1):\n            if (i == n - 1):\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n - 1 - i), range(i, n))\n                qc.x(i)\n        else:\n            # qc.x(i)\n            ll.append(i)\n    for i in ll:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A239BD32ECEBC", "submission_order": 6, "result": "WA", "execution_time": "1010 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in range(n):\n        if ((L >> i) & 1):\n            if (i == n - 1):\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n - 1 - i), range(i, n))\n                qc.x(i)\n        else:\n            qc.x(i)\n            ll.append(i)\n    for i in ll:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A239BD32ECEBC", "submission_order": 7, "result": "WA", "execution_time": "1102 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A239BD32ECEBC", "submission_order": 8, "result": "AC", "execution_time": "1741 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A243F787DE41E", "submission_order": 1, "result": "RE", "execution_time": "853 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.cz(i, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A243F787DE41E", "submission_order": 2, "result": "RE", "execution_time": "815 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        if i > n-1:\n            break\n        qc.cz(i, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A243F787DE41E", "submission_order": 3, "result": "RE", "execution_time": "927 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        if i > n-1:\n            break\n        qc.cz(i-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A264083CAD7DA", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            # lを01列に直してiだけ右シフト\n            if not ((l >> i) & 0b1): # ibit目が1でなければ、フリップ\n                qc.x(i)\n        if n == 1:\n            qc.Z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A264083CAD7DA", "submission_order": 2, "result": "RE", "execution_time": "1551 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            # lを01列に直してiだけ右シフト\n            if not ((l >> i) & 0b1): # ibit目が1でなければ、フリップ\n                qc.x(i)\n        if n == 1:\n            qc.Z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A264083CAD7DA", "submission_order": 3, "result": "RE", "execution_time": "1561 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            # lを01列に直してiだけ右シフト\n            if not ((l >> i) & 0b1): # ibit目が1でなければ、フリップ\n                qc.x(i)\n        if n == 1:\n            qc.Z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A264083CAD7DA", "submission_order": 4, "result": "RE", "execution_time": "1708 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            # lを01列に直してiだけ右シフト\n            if not ((l >> i) & 1): # ibit目が1でなければ、フリップ\n                qc.x(i)\n        if n == 1:\n            qc.Z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A264083CAD7DA", "submission_order": 5, "result": "AC", "execution_time": "2455 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            # lを01列に直してiだけ右シフト\n            if not ((l >> i) & 0b1): # ibit目が1でなければ、フリップ\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A269D8B36F8F0", "submission_order": 1, "result": "AC", "execution_time": "2631 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 1, "result": "RE", "execution_time": "909 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) & 1 == 0:\n                qc.x(i)\n        arr = [0] * n\n        qc.cz(arr, 0)\n        for i in range(n):\n            if (bit >> i) & 1 == 0:\n                qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 2, "result": "RE", "execution_time": "1023 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [0] * n\n        qc.cz(arr, 0)\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 3, "result": "RE", "execution_time": "870 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [0 for i in range(n)]\n        qc.cz(arr, 0)\n        for i in range(n):\n            if (bit >> i) %  == 0:\n                qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 4, "result": "RE", "execution_time": "777 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [0 for i in range(n - 1)]\n        qc.cz(arr, 0)\n        for i in range(n):\n            if (bit >> i) %  == 0:\n                qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 5, "result": "RE", "execution_time": "865 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [0 for i in range(n - 1)]\n        # qc.cz(arr, 0)\n        for i in range(n):\n            if (bit >> i) %  == 0:\n                qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 6, "result": "RE", "execution_time": "868 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for bit in range(L):\n        # for i in range(n):\n        #     if (bit >> i) % 2 == 0:\n        #         qc.x(i)\n        arr = [0 for i in range(n - 1)]\n        qc.cz(arr, 0)\n        # for i in range(n):\n        #     if (bit >> i) %  == 0:\n        #         qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 7, "result": "RE", "execution_time": "982 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for bit in range(L):\n        # for i in range(n):\n        #     if (bit >> i) % 2 == 0:\n        #         qc.x(i)\n        arr = [0 for i in range(n - 1)]\n        qc.cz(arr, n - 1)\n        # for i in range(n):\n        #     if (bit >> i) %  == 0:\n        #         qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 8, "result": "WA", "execution_time": "1123 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L):\n        # for i in range(n):\n        #     if (bit >> i) % 2 == 0:\n        #         qc.x(i)\n        arr = [0 for i in range(n)]\n        qc.cz(arr, n - 1)\n        # for i in range(n):\n        #     if (bit >> i) %  == 0:\n        #         qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 9, "result": "WA", "execution_time": "971 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [0 for i in range(n)]\n        qc.cz(arr, n - 1)\n        # for i in range(n):\n        #     if (bit >> i) %  == 0:\n        #         qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 10, "result": "RE", "execution_time": "837 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [0 for i in range(n)]\n        qc.cz(arr, n - 1)\n        for i in range(n):\n            if (bit >> i) %  == 0:\n                qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 11, "result": "WA", "execution_time": "949 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [0 for i in range(n)]\n        qc.cz(arr, n - 1)\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 12, "result": "RE", "execution_time": "1070 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n        arr = [0 for i in range(n)]\n        qc.cz(arr, 0)\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 13, "result": "RE", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [0 for i in range(n)]\n        qc.cz(arr, 0)\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 14, "result": "WA", "execution_time": "1155 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n        arr = [0 for i in range(n)]\n        qc.cz(arr, n - 1)\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 15, "result": "RE", "execution_time": "865 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L):\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n        arr = [i for i in range(n)]\n        qc.cz(arr, n - 1)\n        for i in range(n):\n            if (bit >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 16, "result": "RE", "execution_time": "865 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L // 2):\n        bit <<= 1\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [i for i in range(1, n)]\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n    \n    if L % 2 == 1:\n        for i in range(1, n):\n            if (L >> i) %2 == 0:\n                qc.x(i)\n        arr = [i for i in range(1, n)]\n        qc.cx(arr, 0)\n        qc.cz(arr, 0)\n        ac.cx(arr, 0)\n        for i in range(1, n):\n            if (L >> i) %2 == 0:\n                qc.x(i)                 \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 17, "result": "WA", "execution_time": "1047 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L // 2):\n        bit <<= 1\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [i for i in range(1, n)]\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n    \n    # if L % 2 == 1:\n    #     for i in range(1, n):\n    #         if (L >> i) %2 == 0:\n    #             qc.x(i)\n    #     arr = [i for i in range(1, n)]\n    #     qc.cx(arr, 0)\n    #     qc.cz(arr, 0)\n    #     ac.cx(arr, 0)\n    #     for i in range(1, n):\n    #         if (L >> i) %2 == 0:\n    #             qc.x(i)                 \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 18, "result": "WA", "execution_time": "935 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L // 2):\n        bit <<= 1\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [i for i in range(1, n)]\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n    \n    if L % 2 == 1:\n        for i in range(1, n):\n            if (L >> i) % 2 == 0:\n                qc.x(i)\n        arr = [i for i in range(1, n)]\n        qc.cx(arr, 0)\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        for i in range(1, n):\n            if (L >> i) %2 == 0:\n                qc.x(i)                 \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 19, "result": "RE", "execution_time": "960 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # if n == 1:\n    #     if L == 1:\n    #         qc.x(0)\n    #         qc.z(0)\n    #         qc.x(0)\n    #     return qc\n\n    for bit in range(L // 2):\n        bit <<= 1\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n        arr = [i for i in range(1, n)]\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(i)\n    \n    if L % 2 == 1:\n        for i in range(1, n):\n            if (L >> i) % 2 == 0:\n                qc.x(i)\n        arr = [i for i in range(1, n)]\n        qc.cx(arr, 0)\n        qc.cz(arr, 0)\n        qc.cx(arr, 0)\n        for i in range(1, n):\n            if (L >> i) % 2 == 0:\n                qc.x(i)                 \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A26EE8D4ACABF", "submission_order": 20, "result": "WA", "execution_time": "1006 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    for bit in range(L // 2):\n        bit <<= 1\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n        arr = [i for i in range(0, n - 1)]\n        qc.cz(arr, n - 1)\n        qc.cx(arr, n - 1)\n        qc.cz(arr, n - 1)\n        qc.cx(arr, n - 1)\n        for i in range(1, n):\n            if (bit >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n    \n    if L % 2 == 1:\n        for i in range(1, n):\n            if (L >> i) % 2 == 0:\n                qc.x(n - 1 - i)\n        arr = [i for i in range(0, n - 1)]\n        qc.cx(arr, n - 1)\n        qc.cz(arr, n - 1)\n        qc.cx(arr, n - 1)\n        for i in range(1, n):\n            if (L >> i) % 2 == 0:\n                qc.x(n - 1 - i)                 \n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A280ACF22BA10", "submission_order": 1, "result": "WA", "execution_time": "1747 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if l >> i != 1:\n                qc.x(i)\n            \n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        if l >> i != 1:\n                qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A280ACF22BA10", "submission_order": 2, "result": "WA", "execution_time": "1924 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if l >> i != 1:\n                qc.x(i)\n            \n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if l >> i != 1:\n                qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A280ACF22BA10", "submission_order": 3, "result": "WA", "execution_time": "1982 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if (l >> i) & 1:\n                qc.x(i)\n            \n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if (l >> i) & 1:\n                qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A280ACF22BA10", "submission_order": 4, "result": "AC", "execution_time": "2016 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if not (l >> i) & 1:\n                qc.x(i)\n            \n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not (l >> i) & 1:\n                qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2A8EED6446F3", "submission_order": 1, "result": "RE", "execution_time": "1295 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2A8EED6446F3", "submission_order": 2, "result": "AC", "execution_time": "2661 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2AA4AAD62B55", "submission_order": 1, "result": "RE", "execution_time": "744 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.rx(pi*2,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 1, "result": "RE", "execution_time": "1395 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:b}\"):\n            if x==\"1\":\n                log.append(j)\n                qc.x(j)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 2, "result": "RE", "execution_time": "1262 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:b}\"):\n            if x==\"1\":\n                log.append(j)\n                qc.x(j)\n\n        if i!=0:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 3, "result": "WA", "execution_time": "1279 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:b}\"):\n            if x==\"1\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 4, "result": "WA", "execution_time": "1316 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:b}\"[::-1]):\n            if x==\"1\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:0{n}b}\"[::-]):\n            if x==\"1\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 6, "result": "WA", "execution_time": "1308 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:0{n}b}\"[::-1]):\n            if x==\"1\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 7, "result": "WA", "execution_time": "1288 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:0{n}b}\"):\n            if x==\"1\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 8, "result": "WA", "execution_time": "1322 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:0{n}b}\"[::-1]):\n            if x==\"0\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 9, "result": "WA", "execution_time": "1452 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:0{n}b}\"):\n            if x==\"0\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 10, "result": "WA", "execution_time": "1396 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:0{n}b}\"[::-1]):\n            if x==\"0\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for x in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ABBF3D33974", "submission_order": 11, "result": "AC", "execution_time": "2879 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:0{n}b}\"[::-1]):\n            if x==\"0\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for j in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2BFE85956028", "submission_order": 1, "result": "RE", "execution_time": "1023 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# def intlog2_math(v):\n#     return int(math.floor(math.log2(v)))\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    M = L.bit_length()\n    b = get_bit(L, M - 1)\n    if b == 0:\n        qc.x(M - 1)\n    else:\n        qc.x(M - 1)\n        qc.z(M - 1)\n        qc.x(M - 1)\n    \n    for i in list(range(M - 1))[::-1]:\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            for j in range(j, M):\n                for k in range(M - i):\n                    qc.cz(k, j)\n            qc.x(i)\n    \n    for i in range(M):\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2BFE85956028", "submission_order": 2, "result": "RE", "execution_time": "923 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# def intlog2_math(v):\n#     return int(math.floor(math.log2(v)))\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    M = L.bit_length()\n    b = get_bit(L, M - 1)\n    if b == 0:\n        qc.x(M - 1)\n    else:\n        qc.x(M - 1)\n        qc.z(M - 1)\n        qc.x(M - 1)\n    \n    for i in list(range(M - 1))[::-1]:\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            for j in range(i, M):\n                for k in range(M - i):\n                    qc.cz(k, j)\n            qc.x(i)\n    \n    for i in range(M):\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2BFE85956028", "submission_order": 3, "result": "WA", "execution_time": "1036 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# def intlog2_math(v):\n#     return int(math.floor(math.log2(v)))\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    M = L.bit_length()\n    b = get_bit(L, M - 1)\n    if b == 0:\n        qc.x(M - 1)\n    else:\n        qc.x(M - 1)\n        qc.z(M - 1)\n        qc.x(M - 1)\n    \n    for i in list(range(M - 1))[::-1]:\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i + 1, M)), i)\n            qc.h(i)\n            qc.x(i)\n    \n    for i in range(M):\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2BFE85956028", "submission_order": 4, "result": "WA", "execution_time": "1199 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# def intlog2_math(v):\n#     return int(math.floor(math.log2(v)))\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    M = L.bit_length()\n    if M == 0:\n        return qc\n    b = get_bit(L, M - 1)\n    if b == 0:\n        qc.x(M - 1)\n    else:\n        qc.x(M - 1)\n        qc.z(M - 1)\n        qc.x(M - 1)\n    \n    for i in list(range(M - 1))[::-1]:\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i + 1, M)), i)\n            qc.h(i)\n            qc.x(i)\n    \n    for i in range(M):\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2BFE85956028", "submission_order": 5, "result": "AC", "execution_time": "2233 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# def intlog2_math(v):\n#     return int(math.floor(math.log2(v)))\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    M = n\n    if M == 0:\n        return qc\n    b = get_bit(L, M - 1)\n    if b == 0:\n        qc.x(M - 1)\n    else:\n        qc.x(M - 1)\n        qc.z(M - 1)\n        qc.x(M - 1)\n    \n    for i in list(range(M - 1))[::-1]:\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i + 1, M)), i)\n            qc.h(i)\n            qc.x(i)\n    \n    for i in range(M):\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 1, "result": "RE", "execution_time": "1025 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        temp = i\n        control = []\n        while(temp > 0):\n            control.append(temp % 2)\n            temp = temp // 2\n\n        while(len(control) < n):\n            control.append(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n        qc.h(0)\n        qc.mcx([i for i in range(1, n)], 0, 0)\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 2, "result": "RE", "execution_time": "1069 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        temp = i\n        control = []\n        while(temp > 0):\n            control.append(temp % 2)\n            temp = temp // 2\n\n        while(len(control) < n):\n            control.append(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n        qc.h(0)\n        qc.mcx([i for i in range(1, n)], 0)\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 3, "result": "RE", "execution_time": "834 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h([i for i in range(n)])\n\n    for i in range(L):\n        temp = i\n        control = []\n        while(temp > 0):\n            control.append(temp % 2)\n            temp = temp // 2\n\n        while(len(control) < n):\n            control.append(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n        qc.h(0)\n        qc.mcx([i for i in range(1, n)], 0, 0)\n        qc.h(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 4, "result": "RE", "execution_time": "950 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        temp = i\n        control = []\n        while(temp > 0):\n            control.append(temp % 2)\n            temp = temp // 2\n\n        while(len(control) < n):\n            control.append(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n        qc.h(0)\n        qc.mcx([i for i in range(1, n)], 0, mode=\"noancilla\")\n        qc.h(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 5, "result": "RE", "execution_time": "1025 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(1):\n        temp = i\n        control = []\n        while(temp > 0):\n            control.append(temp % 2)\n            temp = temp // 2\n\n        while(len(control) < n):\n            control.append(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n        qc.h(0)\n        qc.mcx([i for i in range(1, n)], 0, mode=\"noancilla\")\n        qc.h(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 6, "result": "RE", "execution_time": "1076 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        temp = i\n        control = []\n        while(temp > 0):\n            control.append(temp % 2)\n            temp = temp // 2\n\n        while(len(control) < n):\n            control.append(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n        qc.h(0)\n        qc.mcx([i for i in range(1, n)], 0)\n        qc.h(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 7, "result": "WA", "execution_time": "1164 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        temp = i\n        control = []\n        while(temp > 0):\n            control.append(temp % 2)\n            temp = temp // 2\n\n        while(len(control) < n):\n            control.append(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n        qc.h(0)\n        if n > 1:\n            qc.mcx([i for i in range(1, n)], 0)\n        qc.h(0)\n\n        for j in range(n):\n            if(control[j] == 0):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 8, "result": "WA", "execution_time": "1239 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n        qc.rz(1, 0)\n        return qc\n    else:\n\n        for i in range(L):\n            temp = i\n            control = []\n            while(temp > 0):\n                control.append(temp % 2)\n                temp = temp // 2\n\n            while(len(control) < n):\n                control.append(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(j)\n\n            qc.h(0)\n            qc.mcx([i for i in range(1, n)], 0, mode=\"noancilla\")\n            qc.h(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 9, "result": "WA", "execution_time": "1083 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n        return qc\n    else:\n\n        for i in range(L):\n            temp = i\n            control = []\n            while(temp > 0):\n                control.append(temp % 2)\n                temp = temp // 2\n\n            while(len(control) < n):\n                control.append(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(j)\n\n            qc.h(0)\n            qc.mcx([i for i in range(1, n)], 0, mode=\"noancilla\")\n            qc.h(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 10, "result": "WA", "execution_time": "1035 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n        return qc\n    else:\n\n        for i in range(L):\n            temp = i\n            control = []\n            while(temp > 0):\n                control.append(temp % 2)\n                temp = temp // 2\n\n            while(len(control) < n):\n                control.append(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(j)\n\n            qc.h(0)\n            qc.mcx([i for i in range(1, n)], 0)\n            qc.h(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 11, "result": "RE", "execution_time": "751 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int, L) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    \n    qc = QuantumCircuit(qr)\n    qr = qr[::-1]\n\n    if n == 1:\n        return qc\n    else:\n\n        for i in range(L):\n            temp = i\n            control = []\n            while(temp > 0):\n                control.append(temp % 2)\n                temp = temp // 2\n\n            while(len(control) < n):\n                control.append(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(qr[j])\n\n            qc.h(qr[0])\n            qc.mcx([qr[i] for i in range(1, n)], qr[0], mode=\"noancilla\")\n            qc.h(qr[0])\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 12, "result": "RE", "execution_time": "897 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n    qr = qr[::-1]\n\n    if n == 1:\n        return qc\n    else:\n\n        for i in range(L):\n            temp = i\n            control = []\n            while(temp > 0):\n                control.append(temp % 2)\n                temp = temp // 2\n\n            while(len(control) < n):\n                control.append(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(qr[j])\n\n            qc.h(qr[0])\n            qc.mcx([qr[i] for i in range(1, n)], qr[0], mode=\"noancilla\")\n            qc.h(qr[0])\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 13, "result": "RE", "execution_time": "999 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n    qr = qr[::-1]\n\n    if n == 1:\n        return qc\n    else:\n\n        for i in range(L):\n            temp = i\n            control = []\n            while(temp > 0):\n                control.append(temp % 2)\n                temp = temp // 2\n\n            while(len(control) < n):\n                control.append(0)\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(qr[j])\n\n            qc.h(qr[0])\n            qc.mcx([qr[i] for i in range(1, n)], qr[0],)\n            qc.h(qr[0])\n\n            for j in range(n):\n                if(control[j] == 0):\n                    qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 14, "result": "RE", "execution_time": "832 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qreg = QuantumRegister(n)\n    circuit = QuantumCircuit(qreg)\n\n    for i in range(L):\n        bin_state = format(i, f'0{n}b')[::-1]\n\n        x_gates = [idx for idx, bit in enumerate(bin_state) if bit == '0']\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n        if len(qreg) > 1:\n            circuit.h(qreg[-1])\n            circuit.mcx(qreg[:-1], qreg[-1])\n            circuit.h(qreg[-1])\n        else:\n            circuit.z(qreg[0])\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n    return circuit\n'''"}
{"problem": "QPC001_B3", "user": "A2ED4E9CC9DFC", "submission_order": 15, "result": "AC", "execution_time": "1798 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qreg = QuantumRegister(n)\n    circuit = QuantumCircuit(qreg)\n\n    for i in range(L):\n        bin_state = format(i, f'0{n}b')[::-1]\n\n        x_gates = [idx for idx, bit in enumerate(bin_state) if bit == '0']\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n        if len(qreg) > 1:\n            circuit.h(qreg[-1])\n            circuit.mcx(qreg[:-1], qreg[-1])\n            circuit.h(qreg[-1])\n        else:\n            circuit.z(qreg[0])\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n    return circuit\n'''"}
{"problem": "QPC001_B3", "user": "A3087682DD3E4", "submission_order": 1, "result": "RE", "execution_time": "1369 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2*math.pi\n    for i in range(L-1):\n        qc.ry(theta, i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3087682DD3E4", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2*math.pi\n    for i in range(2^n-1):\n        qc.ry(theta, i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3087682DD3E4", "submission_order": 3, "result": "AC", "execution_time": "2862 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A311EDAE15055", "submission_order": 1, "result": "AC", "execution_time": "1862 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        # |i> -> |2^(n-1)>\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A341529A46FBD", "submission_order": 1, "result": "RE", "execution_time": "797 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        i_ = 2**n - L - 1\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n        qc.mcz([_ in range(n)])\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A341529A46FBD", "submission_order": 2, "result": "RE", "execution_time": "830 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        i_ = 2**n - L - 1\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n        qc.mcp(math.pi, [_ in range(n)])\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A341529A46FBD", "submission_order": 3, "result": "RE", "execution_time": "1051 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        i_ = 2**n - L - 1\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.mcp(math.pi, [_ in range(n - 1)], n - 1)\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A341529A46FBD", "submission_order": 4, "result": "RE", "execution_time": "899 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        i_ = 2**n - L - 1\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.h(n - 1)\n            qc.mcx([_ in range(n - 1)], n - 1)\n            qc.h(n - 1)\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A341529A46FBD", "submission_order": 5, "result": "RE", "execution_time": "1225 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        i_ = 2**n - L - 1\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.h(n - 1)\n            qc.mcx([_ for _ in range(n - 1)], n - 1)\n            qc.h(n - 1)\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.cx(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A341529A46FBD", "submission_order": 6, "result": "RE", "execution_time": "815 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        i_ = 2**n - L - 1\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.h(n - 1)\n            qc.mcx([_ for _in range(n - 1)], n - 1)\n            qc.h(n - 1)\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A341529A46FBD", "submission_order": 7, "result": "AC", "execution_time": "1959 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        i_ = 2**n - i - 1\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.h(n - 1)\n            qc.mcx([_ for _ in range(n - 1)], n - 1)\n            qc.h(n - 1)\n        for j in range(n):\n            if (i_ // (2**j)) % 2 == 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A34EF099C6779", "submission_order": 1, "result": "AC", "execution_time": "2826 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n \ndef add_rule(qc: QuantumCircuit, n: int, suffix: list[int]) -> None:\n    idx = n - 1\n    for bit in suffix:\n        if bit == 0:\n            qc.x(idx)\n        idx -= 1\n\n    k = len(suffix)\n    bits = list(reversed(range(n - 1, n - k - 1, -1))) + [n]\n    qc.append(XGate().control(k), bits)\n\n    idx = n - 1\n    for bit in suffix:\n        if bit == 0:\n            qc.x(idx)\n        idx -= 1\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    minus = QuantumRegister(1)\n    qc.add_bits(minus)\n\n    qc.x(n)\n    qc.h(n)\n\n    suffix = []\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            add_rule(qc, n, suffix + [0])\n            suffix.append(1)\n        else:\n            suffix.append(0)\n\n    qc.h(n)\n    qc.x(n)\n\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A35F40D73CFF4", "submission_order": 1, "result": "RE", "execution_time": "1040 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(5,32)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A35F40D73CFF4", "submission_order": 2, "result": "RE", "execution_time": "845 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.solve(5,3)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A35F40D73CFF4", "submission_order": 3, "result": "RE", "execution_time": "957 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(5,3)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A35F40D73CFF4", "submission_order": 4, "result": "RE", "execution_time": "804 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(5,32)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A35F40D73CFF4", "submission_order": 5, "result": "RE", "execution_time": "891 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(5))\n    qc.cx(5,32)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A37348BB1899E", "submission_order": 1, "result": "AC", "execution_time": "1848 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    Lbit = format(L, f'0{n}b')\n    #print(Lbit)\n    xcx_list = []    \n    for i in range(n):\n        if Lbit[i]=='1':\n            if i==0:\n                qc.z(n-1)\n            else:\n                for j in xcx_list:\n                    qc.x(j)\n                gate_x = XGate().control(i)\n                gate_z = ZGate().control(i)\n                ctrl_qubits = list(range(n-i, n))  # 制御ビットの範囲\n                target_qubit = [n-i-1]\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                qc.append(gate_z, ctrl_qubits + target_qubit)\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                #print(ctrl_qubits)\n                #print(target_qubit)\n                for j in xcx_list:\n                    qc.x(j)\n        else:\n            xcx_list.append(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for j in range(L):\n        qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 2, "result": "RE", "execution_time": "1061 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for j in range(L):\n        qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 3, "result": "RE", "execution_time": "858 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for j in range(L):\n        qc.append(ZGate().control(j - 1), range(j))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 4, "result": "RE", "execution_time": "862 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & j) == j):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & j) == j):\n                qc.x(j)\n    # エンディアンを逆にする\n    qc.reverse_bits()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 5, "result": "RE", "execution_time": "952 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & j) == i):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & j) == i):\n                qc.x(j)\n        qc.barrier()\n    # エンディアンを逆にする\n    qc.reverse_bits()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 6, "result": "RE", "execution_time": "963 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & j) == i):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & j) == i):\n                qc.x(j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_bits()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 7, "result": "RE", "execution_time": "798 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & j) == i):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & j) == i):\n                qc.x(j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    qc.reverse_bits()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 8, "result": "RE", "execution_time": "1341 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & j) == i):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & j) == i):\n                qc.x(j)\n        qc.barrier()\n    # エンディアンを逆にする\n    qc.reverse_bits()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 9, "result": "RE", "execution_time": "938 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & j) == 2**j):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & j) == 2**j):\n                qc.x(j)\n        qc.barrier()\n    # エンディアンを逆にする\n    qc.reverse_bits()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 10, "result": "RE", "execution_time": "994 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # L=0のとき\n    for j in range(n):\n        qc.x(j)\n    qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n        qc.x(j)   \n    qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & 2**j) == 2**j):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & 2**j) == 2**j):\n                qc.x(j)\n        qc.barrier()\n    # エンディアンを逆にする\n    qc.reverse_bits()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 11, "result": "RE", "execution_time": "893 ms", "memory": "87 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # L=0のとき\n    for j in range(n):\n        qc.x(j)\n    qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n        qc.x(j)   \n    qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(j)\n        qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_bits()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 12, "result": "RE", "execution_time": "1043 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # L=0のとき\n    for j in range(n):\n        qc.x(j)\n    qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n        qc.x(j)   \n    qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n -1 - j)\n        qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 13, "result": "UGE", "execution_time": "873 ms", "memory": "89 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    qc.z(0)\n    for j in range(n):\n        qc.x(j)   \n    qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n -1 - j)\n        qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 14, "result": "UGE", "execution_time": "1023 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    qc.z(0)\n    for j in range(n):\n        qc.x(j)   \n    qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n -1 - j)\n        qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 15, "result": "WA", "execution_time": "979 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    qc.z(0)\n    for j in range(n):\n        qc.x(j)   \n    #qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n -1 - j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 16, "result": "WA", "execution_time": "967 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    if(n==1):\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n        qc.x(j)   \n    #qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n -1 - j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 17, "result": "WA", "execution_time": "1020 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    if(n==1):\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n        qc.x(j)   \n    #qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(0, n):\n            if((i & 2**j) != 2**j):\n                qc.x(n -1 - j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 18, "result": "WA", "execution_time": "1019 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    if(n==1):\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n        qc.x(j)   \n    #qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(n -1 - j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 19, "result": "WA", "execution_time": "916 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    if(n==1):\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n        qc.x(j)   \n    #qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 20, "result": "WA", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    if(n==1):\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n        qc.x(j)   \n    #qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 -j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 21, "result": "RE", "execution_time": "931 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    if(n==1):\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n), range(n))\n    for j in range(n):\n        qc.x(j)   \n    #qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 -j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3EB276C490E7", "submission_order": 22, "result": "RE", "execution_time": "931 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # i=0のとき\n    for j in range(n):\n        qc.x(j)\n    if(n==1):\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n), range(n))\n    for j in range(n):\n        qc.x(j)   \n    #qc.barrier()\n    \n    for i in range(1, L):\n        # Zをかけたいビットの0を1にする\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 -j)\n        # cotrolZをかける\n        qc.append(ZGate().control(n - 1), range(n))\n        # Zをかけたいビットの1を0に戻す\n        for j in range(n):\n            if((i & 2**j) != 2**j):\n                qc.x(n - 1 - j)\n        #qc.barrier()\n    # エンディアンを逆にする\n    #qc.reverse_ops()\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3FC5A918A3C1", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.appen(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3FC5A918A3C1", "submission_order": 2, "result": "RE", "execution_time": "1364 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.appen(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3FC5A918A3C1", "submission_order": 3, "result": "AC", "execution_time": "2431 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3FE60BC5B7B9", "submission_order": 1, "result": "RE", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A3FE60BC5B7B9", "submission_order": 2, "result": "AC", "execution_time": "1681 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4104DC8B8213", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Z\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L+1):\n        if (L & 1<<i):\n            qc.x(i)\n        qc.append(Z().control(n-1), range(n))\n        if (L & 1<<i):\n            qc.x(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 1, "result": "UGE", "execution_time": "1318 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import DiagonalGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tdiag = [1] * (1 << n)\n\tfor i in range(L):\n\t\tdiag[i] = -1\n\tqc.append(DiagonalGate(diag), [i for i in range(n)])\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 2, "result": "RE", "execution_time": "692 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, MCMT\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.append(MCMT(ZGate(), n - 1, 1), [i for i in range(n)])\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 3, "result": "UGE", "execution_time": "876 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, MCMT\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n == 1:\n\t\tqc.x(0)\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\tif L == 2:\n\t\t\tqc.z(0)\n\telse:\n\t\tqc.append(MCMT(ZGate(), n - 1, 1), [i for i in range(n)])\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 4, "result": "UGE", "execution_time": "883 ms", "memory": "87 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n == 1:\n\t\tqc.x(0)\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\tif L == 2:\n\t\t\tqc.z(0)\n\telse:\n\t\tqc.append(MCMT(ZGate(), n - 1, 1), [i for i in range(n)])\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 5, "result": "RE", "execution_time": "731 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.append(ZGate(0), 0)\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 6, "result": "RE", "execution_time": "763 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.append(ZGate(), 0)\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 7, "result": "WA", "execution_time": "822 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\t\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 8, "result": "WA", "execution_time": "830 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\t\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 9, "result": "RE", "execution_time": "756 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n >= 2:\n\t\tqc.append(MCMT(ZGate(), 1, 1), 0, 1)\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 10, "result": "UGE", "execution_time": "842 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, MCMT\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n == 1:\n\t\tqc.x(0)\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\tif L == 2:\n\t\t\tqc.z(0)\n\telse:\n\t\tqc.append(MCMT(ZGate(), n - 1, 1), [i for i in range(n)])\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 11, "result": "WA", "execution_time": "901 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, MCMT\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n == 1:\n\t\tqc.x(0)\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\tif L == 2:\n\t\t\tqc.z(0)\n\telse:\n\t\tpass\n\t\t#qc.append(MCMT(ZGate(), n - 1, 1), [i for i in range(n)])\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 12, "result": "RE", "execution_time": "991 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, MCMT\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n == 1:\n\t\tgate = ZGate()\n\t\tqc.x(0)\n\t\tqc.append(gate, 0)\n\t\tqc.x(0)\n\t\tif L == 2:\n\t\t\tqc.z(0)\n\telse:\n\t\tpass\n\t\t#qc.append(MCMT(ZGate(), n - 1, 1), [i for i in range(n)])\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 13, "result": "UGE", "execution_time": "1096 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, MCMT\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n == 1:\n\t\tqc.x(0)\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\tif L == 2:\n\t\t\tqc.z(0)\n\telse:\n\t\tfor i in range(L):\n\t\t\tfor bit in range(n):\n\t\t\t\tif ~i >> bit & 1:\n\t\t\t\t\tqc.x(bit)\n\t\t\tqc.append(MCMT(ZGate(), n - 1, 1), [i for i in range(n)])\n\t\t\tfor bit in range(n):\n\t\t\t\tif ~i >> bit & 1:\n\t\t\t\t\tqc.x(bit)\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 14, "result": "UGE", "execution_time": "1239 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, MCMT\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n == 1:\n\t\tqc.x(0)\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\tif L == 2:\n\t\t\tqc.z(0)\n\telse:\n\t\tfor i in range(L):\n\t\t\tfor bit in range(n):\n\t\t\t\tif ~i >> bit & 1:\n\t\t\t\t\tqc.x(bit)\n\t\t\tqc.append(MCMT(ZGate(), n - 1, 1), [i for i in range(n)])\n\t\t\tfor bit in range(n):\n\t\t\t\tif ~i >> bit & 1:\n\t\t\t\t\tqc.x(bit)\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A45DB445D756C", "submission_order": 15, "result": "AC", "execution_time": "1568 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif n == 1:\n\t\tqc.x(0)\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\tif L == 2:\n\t\t\tqc.z(0)\n\telse:\n\t\tfor i in range(L):\n\t\t\tfor bit in range(n):\n\t\t\t\tif ~i >> bit & 1:\n\t\t\t\t\tqc.x(bit)\n\t\t\tqc.append(ZGate().control(n - 1), [i for i in range(n)])\n\t\t\tfor bit in range(n):\n\t\t\t\tif ~i >> bit & 1:\n\t\t\t\t\tqc.x(bit)\n\treturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A4698C804021C", "submission_order": 1, "result": "RE", "execution_time": "1222 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        for i in range(n):\n            qc.h(i)\n        qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            qc.x(i)\n    elif L == [2 ** i for i in range(1, n + 1)]:\n        qc.z(n - 1)\n        qc.x(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4698C804021C", "submission_order": 2, "result": "RE", "execution_time": "1537 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        for i in range(n):\n            qc.h(i)\n        qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            qc.x(i)\n    elif L == [2 ** i for i in range(1, n + 1)]:\n        qc.z(n - 1)\n        qc.x(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4698C804021C", "submission_order": 3, "result": "AC", "execution_time": "2903 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        for l in range(L):\n            if l & 1 == 0:\n                qc.x(0)\n            qc.z(0)\n            if l & 1 == 0:\n                qc.x(0)\n        return qc\n\n    for l in range(L):\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n        qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A473B008C6F35", "submission_order": 1, "result": "RE", "execution_time": "1407 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    # remove\n    qc.h(range(n))\n\n    x = qulib.ZGate().control(n-1)\n    qc.append(x, range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A473B008C6F35", "submission_order": 2, "result": "RE", "execution_time": "1312 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    # remove\n    qc.h(range(n))\n\n    if n > 1:\n        x = qulib.ZGate().control(n-1)\n        qc.append(x, range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A473B008C6F35", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport matplotlib.pyplot as plt \nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    i = 0\n    while(L > 0):\n        r = L % 2\n        L = L // 2\n        if(r == 1):\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.mcp(math.pi, [x for x in range(i+1, n)], i, ctrl_state=L)\n                qc.x(i)\n\n        i += 1\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A473B008C6F35", "submission_order": 4, "result": "RE", "execution_time": "1871 ms", "memory": "143 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    i = 0\n    while(L > 0):\n        r = L % 2\n        L = L // 2\n        if(r == 1):\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.mcp(math.pi, [x for x in range(i+1, n)], i, ctrl_state=L)\n                qc.x(i)\n\n        i += 1\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A473B008C6F35", "submission_order": 5, "result": "AC", "execution_time": "1649 ms", "memory": "143 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    i = 0\n    while(L > 0) and i < n:\n        r = L % 2\n        L = L // 2\n        if(r == 1):\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.mcp(math.pi, [x for x in range(i+1, n)], i, ctrl_state=L)\n                qc.x(i)\n\n        i += 1\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4836603ECE99", "submission_order": 1, "result": "RE", "execution_time": "776 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.y(qc[i])\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4836603ECE99", "submission_order": 2, "result": "WA", "execution_time": "1000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.y(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4836603ECE99", "submission_order": 3, "result": "RE", "execution_time": "721 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)    \n                \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4836603ECE99", "submission_order": 4, "result": "AC", "execution_time": "2725 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)    \n                \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4C2D37528E8B", "submission_order": 1, "result": "RE", "execution_time": "874 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4D17FCBAC2C2", "submission_order": 1, "result": "AC", "execution_time": "2880 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((l>>i) & 1):\n                qc.x(i)\n\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not((l>>i)&1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4D6947C87D00", "submission_order": 1, "result": "RE", "execution_time": "1810 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef num_inv(qc: QuantumCircuit, n: int, val: int):\n    for i in range(n):\n        if (val >> i) & 1:\n            qc.x(i)\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n    for i in range(n):\n        if (val >> i) & 1:\n            qc.x(i)\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # qc.h(range(n))\n\n    for i in range((1 << n) - L, (1 << n)):\n        num_inv(qc, n, i)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4D6947C87D00", "submission_order": 2, "result": "WA", "execution_time": "1548 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef mcz(qc: QuantumCircuit, n: int):\n    qc.h(0)\n    if n == 1:\n        qc.x(0)\n    else:\n        qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n\ndef num_inv(qc: QuantumCircuit, n: int, val: int):\n    for i in range(n):\n        if (val >> i) & 1:\n            qc.x(i)\n    mcz(qc, n)\n    for i in range(n):\n        if (val >> i) & 1:\n            qc.x(i)\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(range(n))\n\n    for i in range((1 << n) - L, (1 << n)):\n        num_inv(qc, n, i)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4D6947C87D00", "submission_order": 3, "result": "AC", "execution_time": "1962 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef mcz(qc: QuantumCircuit, n: int):\n    qc.h(0)\n    if n == 1:\n        qc.x(0)\n    else:\n        qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n\ndef num_inv(qc: QuantumCircuit, n: int, val: int):\n    for i in range(n):\n        if (val >> i) & 1:\n            qc.x(i)\n    mcz(qc, n)\n    for i in range(n):\n        if (val >> i) & 1:\n            qc.x(i)\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # qc.h(range(n))\n\n    for i in range((1 << n) - L, (1 << n)):\n        num_inv(qc, n, i)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4E93973A640D", "submission_order": 1, "result": "RE", "execution_time": "1679 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.z(range(L))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4E93973A640D", "submission_order": 2, "result": "RE", "execution_time": "1868 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4E93973A640D", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4E93973A640D", "submission_order": 4, "result": "RE", "execution_time": "1825 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A4E93973A640D", "submission_order": 5, "result": "AC", "execution_time": "2185 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5207B8B5B99B", "submission_order": 1, "result": "WA", "execution_time": "969 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52128BE9F05D", "submission_order": 1, "result": "RE", "execution_time": "1048 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # エンコードされた値L-1に対してバイナリ表現を作成\n    Lbinary = format(L-1, '0' + str(n) + 'b')\n    \n    # QC上で必要な制御Zゲートを適用する\n    for i, bit in enumerate(reversed(Lbinary)):\n        if bit == '1':\n            qc.x(i) # 制御されるビットが0のときはXゲートで反転させる\n    \n    # 制御Zゲートを適用する。qiskitでは制御量子ビットの数は制御されるゲートに引数として与える\n    qc.append(ZGate().control(n - 1), range(n))\n    \n    # ビットを元に戻す\n    for i, bit in enumerate(reversed(Lbinary)):\n        if bit == '1':\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52128BE9F05D", "submission_order": 2, "result": "RE", "execution_time": "980 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # We first need a list of binary strings representing the states\n    # that need to have their amplitudes flipped.\n    states_to_flip = [format(i, f\"0{n}b\") for i in range(L)]\n    \n    # For each state, we'll apply a controlled-Z operation, flipping the amplitude\n    for state_string in states_to_flip:\n        # Create a series of gates with X-gates on the qubits that are 0 in the state\n        # because control operations are applied on qubits in the |1> state by default.\n        for qubit_index, state_bit in enumerate(reversed(state_string)):\n            if state_bit == '0':\n                qc.x(qubit_index)\n        \n        # Apply multi-controlled Z gate\n        qc.append(ZGate().control(n-1), range(n))\n        \n        # Undo the X-gates\n        for qubit_index, state_bit in enumerate(reversed(state_string)):\n            if state_bit == '0':\n                qc.x(qubit_index)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52128BE9F05D", "submission_order": 3, "result": "RE", "execution_time": "1039 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMTVChain\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Initialize list for control qubits, which will be all qubits\n    controls = list(range(n))\n    \n    # Determine the binary representation of L-1\n    # and reverse it for little endian order\n    # (This could also be obtained from 'format(L-1, '0{}b'.format(n))')\n    target_state_bin = bin(L-1)[2:].rjust(n, '0')[::-1]\n    \n    # Apply X gates to initialize the controls, flipping 0s to 1s\n    # to obtain the correct control pattern\n    for i, bit in enumerate(target_state_bin):\n        if bit == '0':\n            # Negates the amplitude for states < L\n            qc.x(i)\n    \n    # Apply MCMT (Multi-Control Multi-Target) gate,\n    # since it applies the Z gate only when all controls are 1,\n    # effectively negating the amplitude for the target state.\n    # Here we're creating a Multi-Controlled Z gate targeting a dummy qubit (ignored).\n    # The dummy qubit is used because MCMT requires a target, but Z gate does not have one.\n    qc.append(MCMTVChain('z', num_ctrl_qubits=n, num_target_qubits=1), controls + [n])\n    \n    # Apply X gates again to reset controls\n    for i, bit in enumerate(target_state_bin):\n        if bit == '0':\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52B2820008FF", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for k in range(n):\n        qc.h(k)\n    \n    for i in range(L):\n        # Convert index to n-bit binary and little-endian\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]\n\n        # Apply X gates based on binary representation (make all 1 state)\n        current_qubit = 0\n        for j in range(len(little_endian_binary_repr)):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(current_qubit)\n            current_qubit += 1\n\n        # Apply the multi-controlled gate (MCMT) here\n        # Control qubits are 0 to n-2, target qubit is n-1\n        control_qubits = list(range(n - 1))  # Control qubits from 0 to n-2\n        target_qubit = n - 1  # Target qubit is n-1\n        qc.append(MCMT('z', num_ctrl_qubits=n - 1, num_target_qubits=1), control_qubits + [target_qubit])\n        \n        # Reset X gates for the next iteration\n        current_qubit = 0\n        for j in range(len(little_endian_binary_repr)):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(current_qubit)\n            current_qubit += 1\n    \n    return qc\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for k in range(n):\n        qc.h(k)\n    \n    for i in range(L):\n        # Convert index to n-bit binary and little-endian\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]\n\n        # Apply X gates based on binary representation (make all 1 state)\n        current_qubit = 0\n        for j in range(len(little_endian_binary_repr)):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(current_qubit)\n            current_qubit += 1\n\n        # Apply the multi-controlled gate (MCMT) here\n        # Control qubits are 0 to n-2, target qubit is n-1\n        control_qubits = list(range(n - 1))  # Control qubits from 0 to n-2\n        target_qubit = n - 1  # Target qubit is n-1\n        qc.append(MCMT('z', num_ctrl_qubits=n - 1, num_target_qubits=1), control_qubits + [target_qubit])\n        \n        # Reset X gates for the next iteration\n        current_qubit = 0\n        for j in range(len(little_endian_binary_repr)):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(current_qubit)\n            current_qubit += 1\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52B2820008FF", "submission_order": 2, "result": "RE", "execution_time": "2217 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for k in range(n):\n        qc.h(k)\n    \n    for i in range(L):\n        # Convert index to n-bit binary and little-endian\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]\n\n        # Apply X gates based on binary representation\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n        # Apply the multi-controlled phase gate (equivalent to MCZ)\n        control_qubits = list(range(n - 1))  # Control qubits from 0 to n-2\n        target_qubit = n - 1  # Target qubit is n-1\n        qc.append(MCPhaseGate(lam=np.pi, num_ctrl_qubits=n - 1), control_qubits + [target_qubit])\n        \n        # Reset X gates for the next iteration\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52B2820008FF", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        # Convert index to n-bit binary and little-endian\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]\n\n        # Apply X gates based on binary representation\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n        # Apply the multi-controlled Z gate\n        cz_gate = Gate(name=\"Z\", num_qubits=1, params=[])  # Define a Z gate\n        qc.append(cz_gate.control(n - 1), range(n))  # Apply MCZ\n\n        # Reset X gates for the next iteration\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52B2820008FF", "submission_order": 4, "result": "RE", "execution_time": "1961 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for k in range(n):\n        qc.h(k)\n    \n    for i in range(L):\n        # Convert index to n-bit binary and little-endian\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]\n\n        # Apply X gates based on binary representation\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n        # Apply the multi-controlled Z gate\n        qc.append(ZGate().control(n - 1), range(n))\n\n        # Reset X gates for the next iteration\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52B2820008FF", "submission_order": 5, "result": "RE", "execution_time": "1814 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        # Convert index to n-bit binary and little-endian\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]\n\n        # Apply X gates based on binary representation\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n        # Apply the multi-controlled Z gate\n        qc.append(ZGate().control(n - 1), range(n))\n\n        # Reset X gates for the next iteration\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52B2820008FF", "submission_order": 6, "result": "AC", "execution_time": "2281 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        # Convert index to n-bit binary (big-endian)\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]  # Convert to little-endian\n\n        # Apply X gates based on binary representation\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n        # Apply multi-controlled Z gate\n        if n == 1:\n            qc.z(0)  # Directly apply Z if there's only one qubit\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        # Reset X gates for the next iteration\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52CE0D30FF57", "submission_order": 1, "result": "RE", "execution_time": "1932 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(L-1):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52CE0D30FF57", "submission_order": 2, "result": "RE", "execution_time": "1956 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(L-1):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A52CE0D30FF57", "submission_order": 3, "result": "AC", "execution_time": "2375 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5338F6DF3BC9", "submission_order": 1, "result": "RE", "execution_time": "1016 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qbit in range(n):\n        qc.h(qbit)\n\n    for marked in range(L):\n        b = '{:05b}'.format(marked)[::-1]\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(math.pi, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5338F6DF3BC9", "submission_order": 2, "result": "RE", "execution_time": "1014 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qbit in range(n):\n        qc.h(qbit)\n\n    for marked in range(L):\n        b = '{:05b}'.format(marked)[::-1]\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(math.pi, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5338F6DF3BC9", "submission_order": 3, "result": "RE", "execution_time": "1064 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qbit in range(n):\n        qc.h(qbit)\n\n    for marked in range(L):\n        b = '{:05b}'.format(marked)[::-1]\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(math.pi, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5338F6DF3BC9", "submission_order": 4, "result": "RE", "execution_time": "1043 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qbit in range(n):\n        qc.h(qbit)\n\n    for marked in range(L):\n        b = '{:05b}'.format(marked)[::-1][0:n]\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(math.pi, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5338F6DF3BC9", "submission_order": 5, "result": "RE", "execution_time": "993 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for marked in range(L):\n        b = '{:05b}'.format(marked)[::-1][0:n]\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(math.pi, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if b[zero_bit] == '0':\n                qc.x(zero_bit)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5338F6DF3BC9", "submission_order": 6, "result": "AC", "execution_time": "1999 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\nPI = math.pi\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 0:\n            return qc\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            return qc\n\n    for marked in range(L):\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(PI, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 1, "result": "RE", "execution_time": "830 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(1)\n    qc.z(math.pi / 2.0, 1)\n    qc.x(1)\n\n    qc.cx(1, 0)\n    qc.z(math.pi / 2.0, 0)\n    qc.cx(1, 0)\n\n    qc.x(0)\n    qc.z(math.pi / 2.0, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 2, "result": "RE", "execution_time": "867 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(1)\n    qc.rz(math.pi / 2.0, 1)\n    qc.x(1)\n\n    qc.cx(1, 0)\n    qc.rz(math.pi / 2.0, 0)\n    qc.cx(1, 0)\n\n    qc.x(0)\n    qc.rz(math.pi / 2.0, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 3, "result": "RE", "execution_time": "1124 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(1)\n    qc.rz(math.pi / 2.0, 1)\n    qc.x(1)\n\n    qc.cx(1, 0)\n    qc.rz(math.pi / 2.0, 0)\n    qc.cx(1, 0)\n\n    qc.x(0)\n    qc.rz(math.pi / 2.0, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport ma\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        qc.rz(math.pi / 2.0, 0)\n    if n == 2:\n        qc.x(1)\n        qc.rz(math.pi / 2.0, 1)\n        qc.x(1)\n\n        qc.cx(1, 0)\n        qc.rz(math.pi / 2.0, 0)\n        qc.cx(1, 0)\n\n        qc.x(0)\n        qc.rz(math.pi / 2.0, 0)\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 5, "result": "WA", "execution_time": "960 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        qc.rz(math.pi / 2.0, 0)\n    if n == 2:\n\n        qc.x(1)\n        qc.rz(math.pi / 2.0, 1)\n        qc.x(1)\n\n        qc.cx(1, 0)\n        qc.rz(math.pi / 2.0, 0)\n        qc.cx(1, 0)\n\n        qc.x(0)\n        qc.rz(math.pi / 2.0, 0)\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        qc.rz(math.pi, 0)\n    if n == 2:\n        qc.x(1)\n        qc.rz(math.pi / 2.0, 1)\n        qc.x(1)\n\n        qc.cx(1, 0)\n        qc.rz(math.pi / 2.0, 0)\n        qc.cx(1, 0)\n\n        qc.x(0)\n        qc.rz(math.pi / 2.0, 0)\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 7, "result": "WA", "execution_time": "895 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        qc.rz(math.pi , 0)\n    if n == 2:\n        qc.x(1)\n        qc.rz(math.pi / 2.0, 1)\n        qc.x(1)\n\n        qc.cx(1, 0)\n        qc.rz(math.pi / 2.0, 0)\n        qc.cx(1, 0)\n\n        qc.x(0)\n        qc.rz(math.pi / 2.0, 0)\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 8, "result": "RE", "execution_time": "786 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef (qc, ts):\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    xs = []\n    for i in range(n-1):\n        xs.append(i)\n    qc.mcp(xs, n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 9, "result": "RE", "execution_time": "813 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    xs = []\n    for i in range(n-1):\n        xs.append(i)\n    qc.mcp(xs, n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 10, "result": "RE", "execution_time": "957 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    xs = []\n    for i in range(n-1):\n        xs.append(i)\n    qc.mcp(math.pi, xs, n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 11, "result": "WA", "execution_time": "950 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        qc.z(0)\n    else:\n        xs = []\n        for i in range(n-1):\n            xs.append(i)\n        qc.mcp(math.pi, xs, n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A547222526753", "submission_order": 12, "result": "AC", "execution_time": "1866 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        return qc\n    # 引く\n    L2 = (1 << n) - L\n    print(\"L2 = \", L2)\n    for i in range(n):\n        if L2 & (1 << (n - i - 1)) != 0:\n            print(\"i = \", i)\n            controls = []\n            for k in range(i):\n                controls.append(n-1-k)\n            if len(controls) > 0:\n                qc.mcp(math.pi, controls, n-1-i)\n            else:\n                qc.z(n-1-i)\n            qc.x(n-1-i)\n    for i in reversed(range(n)):\n        if L2 & (1 << (n - i - 1)) != 0:\n            qc.x(n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A56DD94AB5F84", "submission_order": 1, "result": "RE", "execution_time": "1381 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if((i&(1<<j))==0):\n                qc.append(XGate(), [j])\n        qc.append(ZGate().control(1), [0, 1])\n        qc.append(XGate().control(n-1), range(n))\n        for j in range(n):\n            if((i&(1<<j))==0):\n                qc.append(XGate(), [j])\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A56DD94AB5F84", "submission_order": 2, "result": "RE", "execution_time": "1494 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if((i&(1<<j))==0):\n                qc.append(XGate(), [j])\n        qc.append(ZGate().control(n-1), range(n))\n        for j in range(n):\n            if((i&(1<<j))==0):\n                qc.append(XGate(), [j])\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A56DD94AB5F84", "submission_order": 3, "result": "AC", "execution_time": "1627 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if((i&(1<<j))==0):\n                qc.append(XGate(), [j])\n        if(n>1):\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.append(ZGate(), [0])\n        for j in range(n):\n            if((i&(1<<j))==0):\n                qc.append(XGate(), [j])\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A580F6B3773E1", "submission_order": 1, "result": "WA", "execution_time": "1385 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    for l in range(L):\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n        qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A580F6B3773E1", "submission_order": 2, "result": "WA", "execution_time": "1472 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        for l in range(L):\n            if l & 1 == 0:\n                qc.x(0)\n        qc.z(0)\n        for l in range(L):\n            if l & 1 == 0:\n                qc.x(0)\n        return qc\n\n    for l in range(L):\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n        qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A580F6B3773E1", "submission_order": 3, "result": "AC", "execution_time": "2925 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        for l in range(L):\n            # if l & 1 == 0:\n            #     qc.x(0)\n            # qc.z(0)\n            # if l & 1 == 0:\n            #     qc.x(0)\n\n            if l == 0:\n                qc.x(0)\n            qc.z(0)\n            if l == 0:\n                qc.x(0)\n\n        return qc\n\n    for l in range(L):\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n        qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5B2B79BD32C9", "submission_order": 1, "result": "RE", "execution_time": "905 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b = 1<<n\n    # qc.h(0)\n    # qc.h(1)\n    # qc.h(2)\n    for i in range(L):\n        code = bin(i+b)[3:]\n        print(code)\n        zg = ZGate()\n        if code[-1] == \"1\":\n            zg = zg.control(n-1, ctrl_state=code[:-1])\n            qc.append(zg, list(range(n)))\n        else:\n            qc.x(n-1)\n            zg = zg.control(n-1, ctrl_state=code[:-1])\n            qc.append(zg, list(range(n)))\n            qc.x(n-1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5B2B79BD32C9", "submission_order": 2, "result": "RE", "execution_time": "907 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b = 1<<n\n    # qc.h(0)\n    # qc.h(1)\n    # qc.h(2)\n    for i in range(L):\n        code = bin(i+b)[3:]\n        print(code)\n        zg = ZGate()\n        if code[-1] == \"1\":\n            zg = zg.control(n-1, ctrl_state=code[:-1])\n            qc.append(zg, list(range(n)))\n        else:\n            qc.x(n-1)\n            zg = zg.control(n-1, ctrl_state=code[:-1])\n            qc.append(zg, list(range(n)))\n            qc.x(n-1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5B2B79BD32C9", "submission_order": 3, "result": "RE", "execution_time": "1062 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # qc.h(0)\n    # qc.h(1)\n    # qc.h(2)\n    b = 1<<n\n    # qc.h(0)\n    # qc.h(1)\n    # qc.h(2)\n    for i in range(L):\n        code = bin(i+b)[3:]\n        print(code)\n        print(code[:-1])\n        zg = ZGate()\n        if code[0] == \"1\":\n            zg = zg.control(n-1, ctrl_state=code[1:][::-1])\n            qc.append(zg, list(range(n)))\n        else:\n            qc.x(n-1)\n            zg = zg.control(n-1, ctrl_state=code[1:][::-1])\n            qc.append(zg, list(range(n)))\n            qc.x(n-1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5B2B79BD32C9", "submission_order": 4, "result": "WA", "execution_time": "969 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    numbin = bin(L + (1<<n))[3:]\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    print(numbin)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin[1:]):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5B2B79BD32C9", "submission_order": 5, "result": "WA", "execution_time": "983 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    numbin = bin(L + (1<<n))[3:][::-1]\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    print(numbin)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin[1:]):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5B2B79BD32C9", "submission_order": 6, "result": "WA", "execution_time": "926 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    numbin = bin(L + (1<<n))[3:]\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    numbin = numbin.rstrip(\"0\")\n    print(numbin)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5B2B79BD32C9", "submission_order": 7, "result": "AC", "execution_time": "2238 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    numbin = bin(L + (1<<n))[3:]\n    qc = QuantumCircuit(n)\n    numbin = numbin.rstrip(\"0\")\n    print(numbin)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n    qc1 = QuantumCircuit(n)\n    qc1.append(qc, range(n-1,-1,-1))\n    qc1 = qc1.decompose()\n    return qc1\n'''"}
{"problem": "QPC001_B3", "user": "A5B5083B15A46", "submission_order": 1, "result": "RE", "execution_time": "1302 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 1, "result": "RE", "execution_time": "1130 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*np.pi, 0)\n    qc.append(z().control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 2, "result": "RE", "execution_time": "1181 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*np.pi, 0)\n    qc.append(z(n).control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 3, "result": "RE", "execution_time": "1298 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*np.pi, 0)\n    qc.append(z(n-1).control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy\nfrom numpy import pi\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*np.pi, 0)\n    qc.append(ZGate().control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*numpy.pi, 0)\n    qc.append(ZGate().control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*numpy.pi, 0)\n    qc.append(ZGate().control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 7, "result": "RE", "execution_time": "1343 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*numpy.pi, 0)\n    qc.append(ZGate().control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 8, "result": "RE", "execution_time": "1549 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*numpy.pi, 0)\n    qc.append(ZGate().control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 9, "result": "RE", "execution_time": "1311 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*numpy.pi, 0)\n    qc.append(ZGate().control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 10, "result": "RE", "execution_time": "1579 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2*pi, 0)\n    qc.append(ZGate().control(n - 1), range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        return qc\n    else\n        qc.ry(2*npi, 0)\n        qc.append(ZGate().control(n - 1), range(n))\n        return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 12, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        return qc\n    else\n        qc.global_phase = np.pi\n        qc.append(ZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 13, "result": "WA", "execution_time": "1953 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        return qc\n    else:\n        qc.global_phase = np.pi\n        qc.append(ZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 14, "result": "RE", "execution_time": "1794 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        return qc\n    else:\n        for l in range (L):\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n            qc.append(Gate().control(n - 1), range(n))\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 15, "result": "RE", "execution_time": "1982 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        return qc\n    else:\n        for l in range (L):\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n            qc.append(Gate().control(n - 1), range(n))\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n        return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 16, "result": "WA", "execution_time": "2032 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\nfrom numpy import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        return qc\n    else:\n        for l in range (L):\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n            qc.append(ZGate().control(n - 1), range(n))\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n        return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 17, "result": "WA", "execution_time": "1886 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        return qc\n    else:\n        for l in range (L):\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n            qc.append(ZGate().control(n - 1), range(n))\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n        return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 18, "result": "RE", "execution_time": "1809 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range (L):\n        for i in range (n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n            if n==1:\n                qc.append(ZGate)\n            else:\n                qc.append(ZGate().control(n - 1), range(n))\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 19, "result": "WA", "execution_time": "1905 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range (L):\n        for i in range (n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n            if n==1:\n                qc.z(0)\n            else:\n                qc.append(ZGate().control(n - 1), range(n))\n            for i in range (n):\n                if not ((l >> i) & 1):\n                    qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5C27FB2D3E69", "submission_order": 20, "result": "AC", "execution_time": "1955 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range (L):\n        for i in range (n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range (n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 1, "result": "RE", "execution_time": "2090 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n        qc.mcz(list(range(i),i))\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 2, "result": "RE", "execution_time": "1764 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n        qc.mcz(list(range(i)),i)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 3, "result": "RE", "execution_time": "1653 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n        if i!=0:\n            qc.mcz(list(range(i)),i)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 4, "result": "RE", "execution_time": "1633 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def f():\n        qc.append(Gate().control(n - 1), range(n))\n    def g(n):\n        qc.x(n)\n    def h(n):\n        g(n)\n        f(n)\n        if n>0:\n            h(n-1)\n    h(n)\n    g(n)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 5, "result": "RE", "execution_time": "1537 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def f():\n        qc.append(XGate.control(n - 1), range(n))\n    def g(n):\n        qc.x(n)\n    def h(n):\n        g(n)\n        f()\n        if n>0:\n            h(n-1)\n    h(n-1)\n    g(n-1)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 6, "result": "RE", "execution_time": "1812 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nv=0\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    def f():\n        qc.append(ZGate().control(n - 1), range(n))\n    def g(n):\n        qc.x(n)\n    def h(n):\n        global v\n        if n>0:\n            h(n-1)\n        g(n)\n        v^=2**n\n        if v<L:\n            f()\n        if n>0:\n            h(n-1)\n    h(n-1)\n    g(n-1)\n\n\n\n\n    return qc\n#solve(3,4).draw()\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 7, "result": "WA", "execution_time": "1736 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nv=0\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    def f():\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    def g(n):\n        qc.x(n)\n    def h(n):\n        global v\n        if n>0:\n            h(n-1)\n        g(n)\n        v^=2**n\n        if v<L:\n            f()\n        if n>0:\n            h(n-1)\n    h(n-1)\n    g(n-1)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 8, "result": "WA", "execution_time": "1847 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    global v\n    v=2**n-1\n    # Write your code here:\n    def f():\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    def g(n):\n        qc.x(n)\n    def h(n):\n        global v\n        if n>0:\n            h(n-1)\n        g(n)\n        v^=2**n\n        if v<L:\n            f()\n        if n>0:\n            h(n-1)\n    h(n-1)\n    g(n-1)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 9, "result": "RE", "execution_time": "1979 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    global v\n    v=2**n-1\n    # Write your code here:\n    def f():\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    def g(n):\n        qc.x(n)\n    def h(n):\n        global v\n        if n>0:\n            h(n-1)\n        g(n)\n        v^=2**n\n        if v<L:\n            f()\n        if n>0:\n            h(n-1)\n    h(n-1)\n    g(n-1)\n\n    if 2**n==L:\n        qc.append(ZGate().control(n - 1), range(n))\n\n\n\n\n    return qc\nsolve(4,16).draw()\n'''"}
{"problem": "QPC001_B3", "user": "A5DC9C3AFD20D", "submission_order": 10, "result": "AC", "execution_time": "2077 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    global v\n    v=2**n-1\n    # Write your code here:\n    def f():\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    def g(n):\n        qc.x(n)\n    def h(n):\n        global v\n        if n>0:\n            h(n-1)\n        g(n)\n        v^=2**n\n        if v<L:\n            f()\n        if n>0:\n            h(n-1)\n    h(n-1)\n    g(n-1)\n\n    if 2**n==L:\n        f()\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A603AE4A6F180", "submission_order": 1, "result": "RE", "execution_time": "2140 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply phase flip to states |0⟩ to |L-1⟩\n    for i in range(L):\n        binary_str = format(i, f'0{n}b')  # Convert to binary with n bits\n        \n        # Apply X gates to prepare the |i⟩ state\n        for j, bit in enumerate(reversed(binary_str)):\n            if bit == '0':\n                qc.x(j)\n        \n        # Multi-controlled Z gate\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n        \n        # Revert the X gates\n        for j, bit in enumerate(reversed(binary_str)):\n            if bit == '0':\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A612EAEE35719", "submission_order": 1, "result": "RE", "execution_time": "1735 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if (l & (1<<i)):\n                continue\n            else:\n                qc.x(i)\n        qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (l & (1<<i)):\n                continue\n            else:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A612EAEE35719", "submission_order": 2, "result": "AC", "execution_time": "2832 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if (l & (1<<i)):\n                continue\n            else:\n                qc.x(i)\n        ## n == 1のときの例外処理\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (l & (1<<i)):\n                continue\n            else:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6245CF463BF9", "submission_order": 1, "result": "WA", "execution_time": "959 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6245CF463BF9", "submission_order": 2, "result": "RE", "execution_time": "897 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.cx(0:n-2,n-1)\n    qc.h(n-1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6245CF463BF9", "submission_order": 3, "result": "RE", "execution_time": "1001 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.cx(range(0:n-2),n-1)\n    qc.h(n-1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6245CF463BF9", "submission_order": 4, "result": "RE", "execution_time": "1019 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.mcx(range(0:n-2),n-1)\n    qc.h(n-1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6245CF463BF9", "submission_order": 5, "result": "RE", "execution_time": "880 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.mcx([0:n-2],n-1)\n    qc.h(n-1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6245CF463BF9", "submission_order": 6, "result": "RE", "execution_time": "890 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)),n-1)\n    qc.h(n-1)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6245CF463BF9", "submission_order": 7, "result": "RE", "execution_time": "1168 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        binary_l = format(l, f'0{n}b')\n\n        for qubit, bit in enumerate(binary_l):\n            if bit == '0':\n                qc.x(qubit)\n\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n\n        for qubit, bit in enumerate(binary_l):\n            if bit == '0':\n                qc.x(qubit)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6245CF463BF9", "submission_order": 8, "result": "RE", "execution_time": "911 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # すべての量子ビットにアダマール変換を適用\n    for q in range(n):\n        qc.h(q)\n\n    # |0>, |1>, ..., |L-1> に対して位相反転\n    for i in range(L):\n        # iをnビットのバイナリ表現に変換\n        binary_i = format(i, '0' + str(n) + 'b')\n\n        # ビットが0の場合にXゲートを適用（位相キックバックを使用）\n        for qubit, bit in enumerate(reversed(binary_i)):\n            if bit == '0':\n                qc.x(qubit)\n\n        # すべての量子ビットに制御Zゲートを適用\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n\n        # ビットが0の場合にXゲートを適用\n        for qubit, bit in enumerate(reversed(binary_i)):\n            if bit == '0':\n                qc.x(qubit)\n\n    # すべての量子ビットにアダマール変換を適用\n    for q in range(n):\n        qc.h(q)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6257205C7E71", "submission_order": 1, "result": "RE", "execution_time": "768 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if str_int[i] == '1':\n            ctr_state = (str_int[:i])\n            print(ctr_state)\n            cx = qiskit.circuit.library.standard_gates.ZGate().control(i, ctrl_state=ctr_state)\n            qc.append(cx, list(range(i+1)))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6257205C7E71", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport qiskit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if str_int[i] == '1':\n            ctr_state = (str_int[:i])\n            print(ctr_state)\n            cx = qiskit.circuit.library.standard_gates.ZGate().control(i, ctrl_state=ctr_state)\n            qc.append(cx, list(range(i+1)))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6257205C7E71", "submission_order": 3, "result": "RE", "execution_time": "1164 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport qiskit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    str_int = str(bin(L)).replace('0b', '').zfill(n)\n    # Write your code here:\n    for i in range(n):\n        if str_int[i] == '1':\n            ctr_state = (str_int[:i])\n            print(ctr_state)\n            cx = qiskit.circuit.library.standard_gates.ZGate().control(i, ctrl_state=ctr_state)\n            qc.append(cx, list(range(i+1)))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 1, "result": "RE", "execution_time": "900 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(L):\n        qc.z(i)  # 各状態に対してZゲートを適用\n\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 2, "result": "RE", "execution_time": "930 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(L):\n        qc.cz(i)  # 各状態に対してZゲートを適用\n\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 3, "result": "RE", "execution_time": "1048 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(L):\n        qc.z(i)  # 各状態に対してZゲートを適用\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 4, "result": "RE", "execution_time": "757 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n     for i in range(n):\n        qc.h(i)  # アダマールゲートを適用\n        qc.z(i)  # 各状態に対してZゲートを適用\n        qc.h(i)  # アダマールゲートを再度適用\n    \n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 5, "result": "WA", "execution_time": "938 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(n):\n        qc.x([i])\n\n    \n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 6, "result": "WA", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(n):\n        qc.z([i])\n\n    \n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 7, "result": "RE", "execution_time": "944 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(L):\n        qc.z([i])\n\n    \n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 8, "result": "WA", "execution_time": "860 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(n):\n        qc.h([i])\n        qc.x([i])\n        qc.h([i])\n\n  \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 9, "result": "WA", "execution_time": "987 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(n):\n        qc.h([i])\n        qc.x([i])\n        qc.h([i])\n        qc.z([i])\n\n  \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 10, "result": "RE", "execution_time": "910 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(n):\n        qc.x(i)  # 各量子ビットにXゲートを適用\n        qc.cz(i, n)  # 各量子ビットと補助ビット（nビット目）に対してControlled-Zゲートを適用\n        qc.x(i)  \n\n\n  \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A627ED8315008", "submission_order": 11, "result": "RE", "execution_time": "900 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     # オラクルの実装\n    for i in range(n):\n        qc.x([i])  # 各量子ビットにXゲートを適用\n        qc.cz([i], [n])  # 各量子ビットと補助ビット（nビット目）に対してControlled-Zゲートを適用\n        qc.x([i])  \n\n\n  \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A62E4D2EB3600", "submission_order": 1, "result": "RE", "execution_time": "1678 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    for l in range(L):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        # multi-controlled-Zゲートを適用\n        qc.mcz(range(n-1), n-1)\n        # 状態の復元\n        # 理由：オラクル適用のために行った一時的な変更を元に戻すため\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A63505A2F5858", "submission_order": 1, "result": "WA", "execution_time": "1276 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.z(i)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A63505A2F5858", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if((1&bin(i>>j)) == 0) qc.x(j)\n        qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if((1&bin(i>>j)) == 0) qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A63505A2F5858", "submission_order": 3, "result": "RE", "execution_time": "1163 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if((1&bin(i>>j)) == 0):\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if((1&bin(i>>j)) == 0):\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A63505A2F5858", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if((1&bin(i>>j)) == 0):\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if((1&bin(i>>j)) == 0):\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A63505A2F5858", "submission_order": 5, "result": "RE", "execution_time": "1168 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if((1&bin(i>>j)) == 0):\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if((1&bin(i>>j)) == 0):\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A63505A2F5858", "submission_order": 6, "result": "AC", "execution_time": "2144 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        for j in range(n):\n            if not (1&(i>>j)):\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if not (1&(i>>j)):\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A0D52011056", "submission_order": 1, "result": "AC", "execution_time": "2113 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        # |i> -> |2^(n-1)>\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A89D49EFB4E", "submission_order": 1, "result": "WA", "execution_time": "1413 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A89D49EFB4E", "submission_order": 2, "result": "RE", "execution_time": "1620 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A9644433C1F", "submission_order": 1, "result": "RE", "execution_time": "1733 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for mask in range(L):\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A9644433C1F", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for mask in range(L):\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n            for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A9644433C1F", "submission_order": 3, "result": "RE", "execution_time": "1701 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for mask in range(L):\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A9644433C1F", "submission_order": 4, "result": "RE", "execution_time": "1962 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L <= 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L <= 2:\n            qc.z(0)\n\n    for mask in range(L):\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A9644433C1F", "submission_order": 5, "result": "WA", "execution_time": "1762 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L <= 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L <= 2:\n            qc.z(0)\n        return qc\n\n    for mask in range(L):\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6A9644433C1F", "submission_order": 6, "result": "AC", "execution_time": "1853 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L >= 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L >= 2:\n            qc.z(0)\n        return qc\n\n    for mask in range(L):\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if (((1<<i) & mask) == 0):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6AAC19CE11ED", "submission_order": 1, "result": "RE", "execution_time": "1071 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    from qiskit.circuit.library import ZGate\n\n    for  i in range(L):\n        for j in range(n):\n            if(not ((i>>j)&1)):\n                qc.x(j)\n        qc.append(ZGate().control(n-1),range(n))\n        for i in range(n):\n            if not ((j >> i) & 1):\n                qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6AAC19CE11ED", "submission_order": 2, "result": "RE", "execution_time": "1370 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    from qiskit.circuit.library import ZGate\n\n    for  i in range(L):\n        for j in range(n):\n            if(not ((i>>j)&1)):\n                qc.x(j)\n        qc.append(ZGate().control(n-1),range(n))\n        for i in range(n):\n            if not ((j >> i) & 1):\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6AAC19CE11ED", "submission_order": 3, "result": "WA", "execution_time": "998 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    from qiskit.circuit.library import ZGate\n\n    for  i in range(L):\n        for j in range(n):\n            if(not ((i>>j)&1)):\n                qc.x(j)\n        if(n==1):\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))        \n        for i in range(n):\n            if not ((j >> i) & 1):\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6AAC19CE11ED", "submission_order": 4, "result": "WA", "execution_time": "981 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    from qiskit.circuit.library import ZGate\n\n    for  i in range(L):\n        for j in range(n):\n            if(not ((i>>j)&1)):\n                qc.x(j)\n        if(n==1):\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))        \n        for i in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6AAC19CE11ED", "submission_order": 5, "result": "AC", "execution_time": "1891 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    from qiskit.circuit.library import ZGate\n\n    for  i in range(L):\n        for j in range(n):\n            if(not ((i>>j)&1)):\n                qc.x(j)\n        if(n==1):\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))        \n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 1, "result": "RE", "execution_time": "866 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(n-1)\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[0:n-1]\n        if i<2**(n-1):\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n        else:\n            print(i, cs)\n            qc.x(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.x(n-1)\n    qc.h(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 2, "result": "RE", "execution_time": "922 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(n-1)\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[0:n-1]\n        if i<2**(n-1):\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n        else:\n            print(i, cs)\n            qc.x(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.x(n-1)\n    qc.h(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 3, "result": "RE", "execution_time": "961 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(n-1)\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[0:n-1]\n        if i<2**(n-1):\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n        else:\n            qc.x(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.x(n-1)\n    qc.h(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 4, "result": "RE", "execution_time": "1011 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(n-1)\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[-(n-1):]\n        if i<2**(n-1):\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n        else:\n            qc.x(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.x(n-1)\n    qc.h(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 5, "result": "RE", "execution_time": "884 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(n-1)\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[-(n-1):]\n        if i<2**(n-1):\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n        else:\n            qc.x(n-1)\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n            qc.x(n-1)\n    qc.h(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 6, "result": "RE", "execution_time": "980 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[-(n-1):]\n        if i<2**(n-1):\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n        else:\n            qc.x(n-1)\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n            qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 7, "result": "RE", "execution_time": "1016 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[-(n-1):]\n        if i<2**(n-1):\n            qc.x(n-1)\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n            qc.x(n-1)\n        else:\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 8, "result": "RE", "execution_time": "920 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n==1:\n        if L=1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        else:\n            qc.z(0)\n        return qc\n\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[-(n-1):]\n        if i<2**(n-1):\n            qc.x(n-1)\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n            qc.x(n-1)\n        else:\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6CF040C8455F", "submission_order": 9, "result": "AC", "execution_time": "2245 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n==1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        if L==2:\n            qc.z(0)\n        return qc\n\n    for i in range(L):\n        cs=str(format(i, '0'+str(n-1)+'b'))[-(n-1):]\n        if i<2**(n-1):\n            qc.x(n-1)\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n            qc.x(n-1)\n        else:\n            qc.h(n-1)\n            qc.append(MCXGate(n-1, ctrl_state=cs), range(n))\n            qc.h(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6E2D64590B76", "submission_order": 1, "result": "UGE", "execution_time": "1404 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n        qc.barrier()\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6E2D64590B76", "submission_order": 2, "result": "AC", "execution_time": "1637 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 1, "result": "RE", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(x().control(i),range(i,n))\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 2, "result": "RE", "execution_time": "844 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(x().control(i),range(n-1,i-1,-1))\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 3, "result": "RE", "execution_time": "794 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.mcp(math.pi, range(i+1,n), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 4, "result": "RE", "execution_time": "860 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            %qc.mcp(math.pi, range(i+1,n), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 5, "result": "WA", "execution_time": "1097 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            #qc.mcp(math.pi, range(i+1,n), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 6, "result": "RE", "execution_time": "1046 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(MCPhaseGate(math.pi).control(i), range(i+1,n))\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 7, "result": "RE", "execution_time": "768 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(MCPhaseGate(math.pi).control(n-i+1), range(n,i-1,-1))\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 8, "result": "RE", "execution_time": "829 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(PhaseGate(theta = math.pi).control(num_ctrl_qubits = n-i+1), qargs = range(n,i-1,-1))\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 9, "result": "RE", "execution_time": "1050 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.mcp(math.pi, range(i+1,n), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 10, "result": "RE", "execution_time": "1113 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.mcp(math.pi, range(i,n), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 11, "result": "RE", "execution_time": "899 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.mcp(math.pi, range(n-1, i, -1), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 12, "result": "RE", "execution_time": "977 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(ZGate().control(i), range(n-1, i, -1), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 13, "result": "RE", "execution_time": "892 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(ZGate().control(i), range(1,n), 0)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 14, "result": "RE", "execution_time": "1033 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(ZGate().control(0), range(1,n))\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 15, "result": "RE", "execution_time": "951 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(ZGate().control(n-1), range(1,n))\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 16, "result": "WA", "execution_time": "1054 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(ZGate().control(n-1), range(n))\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6F13D91A43B7", "submission_order": 17, "result": "AC", "execution_time": "1322 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.mcp(math.pi, list(range(i+1,n)), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6FAABB7E3F4D", "submission_order": 1, "result": "RE", "execution_time": "932 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.h(i)\n\n    qc.append(ZGate().control(n - 1), range(L))\n\n    for i in range(n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6FAABB7E3F4D", "submission_order": 2, "result": "RE", "execution_time": "874 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.h(i)\n\n    qc.append(XGate().control(n - 1), range(L - 1))\n\n    for i in range(n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6FAABB7E3F4D", "submission_order": 3, "result": "RE", "execution_time": "900 ms", "memory": "87 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.h(i)\n\n    qc.append(ZGate().control(n - 1), range(L - 1))\n\n    for i in range(n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6FAABB7E3F4D", "submission_order": 4, "result": "RE", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.h(i)\n\n    qc.append(ZGate().control(n - 1), range(2))\n\n    for i in range(n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6FAABB7E3F4D", "submission_order": 5, "result": "RE", "execution_time": "826 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.h(i)\n\n    if n == 2:\n        qc.append(ZGate().control(n - 1), range(L - 1))\n    elif n == 3:\n        qc.append(ZGate().control(n - 1), range(int((L - 1) // 2) - 1))\n    elif n == 4:\n        qc.append(ZGate().control(n - 1), range(int((L - 1) // 4)))\n    elif n == 5:\n        qc.append(ZGate().control(n - 1), range(int((L - 1) // 8) - 1))\n\n    for i in range(n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6FAABB7E3F4D", "submission_order": 6, "result": "RE", "execution_time": "934 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.h(i)\n        qc.z(i)\n\n    if n == 2:\n        qc.append(ZGate().control(n - 1), range(L - 1))\n    elif n == 3:\n        qc.append(ZGate().control(n - 1), range(int((L // 2) - 1)))\n    elif n == 4:\n        qc.append(ZGate().control(n - 1), range(int((L // 4) - 1)))\n    elif n == 5:\n        qc.append(ZGate().control(n - 1), range(int((L // 8) - 1)))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A6FAABB7E3F4D", "submission_order": 7, "result": "RE", "execution_time": "905 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # qc.append(ZGate().control(n - 1), range(n))\n    # for i in range(n):\n    # qc.h(i)\n    # qc.z(i)\n\n    if n == 2:\n        qc.append(ZGate().control(n - 1), range(L - 1))\n    elif n == 3:\n        qc.append(ZGate().control(n - 1), range(int((L // 2) - 1)))\n    elif n == 4:\n        qc.append(ZGate().control(n - 1), range(int((L // 4) - 1)))\n    elif n == 5:\n        qc.append(ZGate().control(n - 1), range(int((L // 8) - 1)))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A70AA91870A01", "submission_order": 1, "result": "RE", "execution_time": "961 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for j in range((1 << n) - L):\n        for i in range(n):\n            if((j >> i) & 1):\n                qc.x(i)\n        qc.mcp(math.pi, qc.qregs[0][:n-1], qc.qregs[0][n-1])\n        for i in range(n):\n            if((j >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A70AA91870A01", "submission_order": 2, "result": "RE", "execution_time": "1041 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range((1 << n) - L):\n        for i in range(n):\n            if((j >> i) & 1):\n                qc.x(i)\n        qc.mcp(math.pi, qc.qregs[0][:n-1], qc.qregs[0][n-1])\n        for i in range(n):\n            if((j >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A70AA91870A01", "submission_order": 3, "result": "AC", "execution_time": "1833 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 1:\n            qc.p(math.pi, 0)\n    else:\n        for j in range((1 << n) - L):\n            for i in range(n):\n                if((j >> i) & 1):\n                    qc.x(i)\n            qc.mcp(math.pi, qc.qregs[0][:n-1], qc.qregs[0][n-1])\n            for i in range(n):\n                if((j >> i) & 1):\n                    qc.x(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A726A4D30E5DE", "submission_order": 1, "result": "RE", "execution_time": "1266 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A726A4D30E5DE", "submission_order": 2, "result": "RE", "execution_time": "1225 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A74230A11D002", "submission_order": 1, "result": "AC", "execution_time": "1696 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n\n    # L未満の状態に-1の位相を加えるための回路を構築\n    for i in range(L):\n        # リトルエンディアンで整数をエンコードするためのビットパターンを生成\n        bit_pattern = '{:0{}b}'.format(i, n)\n\n        # ビットパターンに合わせてXゲートを適用\n        for qubit, bit in enumerate(reversed(bit_pattern)):\n            if bit == '0':\n                qc.x(qubit)\n\n        # 制御Zゲートを適用\n        if n > 1:\n            qc.h(n-1)\n            qc.mcx(list(range(n-1)), n-1)\n            qc.h(n-1)\n        else:\n            qc.z(0)\n\n        # Xゲートを元に戻す\n        for qubit, bit in enumerate(reversed(bit_pattern)):\n            if bit == '0':\n                qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A75752A70F043", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #L = 2^m + a となる最大のmを求めて\n    m = int(L/2);\n    a = L - 2**m;\n    #m-1キュビットまでは、mキュビット以上をX=>Z でOK\n    for i in range(m,n):\n        qc.x(i);\n        qc.z(i);\n        qc.x(i);\n    #で,a分だけはCNOTで場合分けしながら,\n    for i in range(a+1):\n        \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A75752A70F043", "submission_order": 2, "result": "WA", "execution_time": "1894 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #L = 2^m + a となる最大のmを求めて\n    m = int(L/2);\n    a = L - 2**m;\n    #m-1キュビットまでは、mキュビット以上をX=>Z でOK\n    for i in range(m,n):\n        qc.x(i);\n        qc.z(i);\n        qc.x(i);\n    #で,a分だけはCNOTで場合分けしながら,\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A75752A70F043", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #最善はL が2^nより大きいか小さいかで場合分けするのがいちばんいい。\n    #L = 2^m + a となる最大のmを求めて\n    m = int(L/2);\n    a = L - 2**m;\n    #m-1キュビットまでは、mキュビット以上をX=>Z でOK\n    for i in range(m,n):\n        qc.x(i);\n        qc.z(i);\n        qc.x(i);\n    #で,a分だけはCNOTで場合分けしながら,\n    #iに応じて、各0~m-1キュビットまでにXつけるかどうか.\n    #その後にCCCCCZをかましたい.\n    for i in range(a+1):\n        qc.append(Gate().control())\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B04D53194FF", "submission_order": 1, "result": "RE", "execution_time": "1545 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if l & (1 << i):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        if l & (1 << i):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B04D53194FF", "submission_order": 2, "result": "RE", "execution_time": "1862 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if l & (1 << i):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        if l & (1 << i):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B04D53194FF", "submission_order": 3, "result": "WA", "execution_time": "1550 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if l & (1 << i):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        if l & (1 << i):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B04D53194FF", "submission_order": 4, "result": "WA", "execution_time": "1445 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not(l & (1 << i)):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        if not(l & (1 << i)):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B04D53194FF", "submission_order": 5, "result": "AC", "execution_time": "2676 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not(l & (1 << i)):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not(l & (1 << i)):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 1, "result": "RE", "execution_time": "933 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        qc.cz(0, range(1, n))\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 2, "result": "RE", "execution_time": "792 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        qc.cz(range(0, n-1), n-1)\n        qc.x(xlis)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 3, "result": "RE", "execution_time": "2425 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        qc.cz(range(0, n-1), n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 4, "result": "RE", "execution_time": "948 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        qc.cz(range(0, n-1), n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 5, "result": "RE", "execution_time": "1075 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        for j in range(n-1):\n            qc.cz(j, n-1)\n        if n%2 == 1:\n            qc.z(0)\n            qc.x(0)\n            qx.z(0)\n            qx.x(0)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 6, "result": "RE", "execution_time": "866 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        if n%2 == 1:\n            qc.z(0)\n            qc.x(0)\n            qx.z(0)\n            qx.x(0)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 7, "result": "RE", "execution_time": "879 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        #qc.x(xlist)\n        for j in range(n-1):\n            qc.cz(j, n-1)\n        if n%2 == 1:\n            qc.z(0)\n            qc.x(0)\n            qx.z(0)\n            qx.x(0)\n        #qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 8, "result": "WA", "execution_time": "942 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 9, "result": "WA", "execution_time": "1048 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        #for j in range(n-1):\n        #    qc.cz(j, n-1)\n        #if n%2 == 1:\n        #    qc.z(0)\n        #    qc.x(0)\n        #    qx.z(0)\n        #    qx.x(0)\n        #qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 10, "result": "WA", "execution_time": "899 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        for j in range(n-1):\n            qc.cz(j, n-1)\n        #if n%2 == 1:\n        #    qc.z(0)\n        #    qc.x(0)\n        #    qx.z(0)\n        #    qx.x(0)\n        #qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 11, "result": "RE", "execution_time": "881 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        for j in range(n-1):\n            qc.cz(j, n-1)\n        if n%2 == 1:\n            qc.z(0)\n            qc.x(0)\n            qx.z(0)\n            qx.x(0)\n        #qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 12, "result": "WA", "execution_time": "905 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        for j in range(n-1):\n            qc.cz(j, n-1)\n        #if n%2 == 1:\n        #    qc.z(0)\n        #    qc.x(0)\n        #    qx.z(0)\n        #    qx.x(0)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 13, "result": "WA", "execution_time": "1208 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        for j in range(n-1):\n            qc.cz(j, n-1)\n        if n%2 == 1:\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 14, "result": "WA", "execution_time": "920 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 15, "result": "RE", "execution_time": "1188 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        else:\n            qx.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 16, "result": "WA", "execution_time": "987 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = []\n        for j in range(n):\n            if ((i>>j)&1) == 0:\n                xlist.append(j)\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        else:\n            qc.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 17, "result": "WA", "execution_time": "927 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        else:\n            qc.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 18, "result": "WA", "execution_time": "836 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        else:\n            qc.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 19, "result": "RE", "execution_time": "797 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n), n-1)\n        else:\n            qc.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 20, "result": "RE", "execution_time": "934 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n), n-1)\n        else:\n            qc.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 21, "result": "WA", "execution_time": "1071 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(1, n), 0)\n        else:\n            qc.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 22, "result": "RE", "execution_time": "956 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(1, n), 0)\n        else:\n            qc.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 23, "result": "WA", "execution_time": "979 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range((1<<n)):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        if len(xlist) == 0:\n            continue\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(1, n), 0)\n        else:\n            qc.z(n-1)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 24, "result": "RE", "execution_time": "911 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(range(n))\n    qc.x(0)\n    qx.z(range(n))\n    qc.x(0)\n    if n > 1:\n        qc.cz(range(1, n), 0)\n    else:\n        qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 25, "result": "WA", "execution_time": "989 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #qc.z(range(n))\n    qc.x(0)\n    #qx.z(range(n))\n    qc.x(0)\n    if n > 1:\n        qc.cz(range(1, n), 0)\n    else:\n        qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 26, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.z(i)\n    qc.x(0)\n    for i in range(n):\n        qc.z(i)\n    qc.x(0)\n    if n > 1:\n        qc.cz(range(1, n), 0)\n    else:\n        qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 27, "result": "WA", "execution_time": "979 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    if n > 1:\n        qc.cz(range(1, n), 0)\n    else:\n        qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 28, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Z\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    if n > 1:\n        qc.append(Z().control(range(1, n)), 0)\n    else:\n        qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 29, "result": "RE", "execution_time": "915 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    if n > 1:\n        qc.append(ZGate().control(range(1, n)), 0)\n    else:\n        qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 30, "result": "RE", "execution_time": "1249 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    if n > 1:\n        qc.append(ZGate().control(0)), range(1, n))\n    else:\n        qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 31, "result": "RE", "execution_time": "843 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    if n > 1:\n        qc.append(ZGate().control(0), range(1, n))\n    else:\n        qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 32, "result": "WA", "execution_time": "904 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        else:\n            qc.z(0)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 33, "result": "RE", "execution_time": "895 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.append(ZGate().control(range(n-1)), [0])\n        else:\n            qc.z(0)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 34, "result": "RE", "execution_time": "870 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz([j for j in range(n) if j != i], i)\n        else:\n            qc.z(0)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 35, "result": "RE", "execution_time": "997 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n-1):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        qc.x(xlist)\n        if n > 1:\n            qc.cz([j for j in range(n) if 1<<j != i], i)\n        else:\n            qc.z(0)\n        qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 36, "result": "RE", "execution_time": "889 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        if len(xlist) != 0:\n            qc.x(xlist)\n        if n > 1:\n            qc.cz([j for j in range(n) if 1<j != i], i)\n        else:\n            qc.z(0)\n        if len(xlist) != 0:\n            qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 37, "result": "WA", "execution_time": "1018 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1<<n):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        if len(xlist) != 0:\n            qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        else:\n            qc.z(0)\n        if len(xlist) != 0:\n            qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 38, "result": "WA", "execution_time": "1006 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        xlist = [j for j in range(n) if ((i>>j)&1) == 0]\n        if len(xlist) != 0:\n            qc.x(xlist)\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        else:\n            qc.z(0)\n        if len(xlist) != 0:\n            qc.x(xlist)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 39, "result": "WA", "execution_time": "933 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        [qc.x(j) for j in range(n) if ((i>>j)&1) == 0]\n        if n > 1:\n            qc.cz(range(0, n-1), n-1)\n        else:\n            qc.z(0)\n        [qc.x(j) for j in range(n) if ((i>>j)&1) == 0]\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7B14A74E8FF3", "submission_order": 40, "result": "AC", "execution_time": "2546 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        [qc.x(j) for j in range(n) if ((i>>j)&1) == 0]\n        if n > 1:\n            qc.append(ZGate().control(n - 1), range(n))\n        else:\n            qc.z(0)\n        [qc.x(j) for j in range(n) if ((i>>j)&1) == 0]\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7C88FB86D610", "submission_order": 1, "result": "RE", "execution_time": "1014 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    now = n - 1\n    tmp0 = []\n\n    while(now >= 0):\n        if(now == n - 1):\n            if((L & (1 << now))):\n                qc.rz(math.pi * 2, now)\n                #qc.z(now)\n            else:\n                qc.rz(math.pi * 2, now)\n                qc.z(now)\n                tmp0.append(now)\n                qc.x(now)\n        else:\n            if((L & (1 << now))):\n                #qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n            else:\n                qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n\n                tmp0.append(now)\n                qc.x(now)\n\n        now -= 1\n\n\n    for x in tmp0:\n        qc.x(x)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7C88FB86D610", "submission_order": 2, "result": "WA", "execution_time": "907 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    now = n - 1\n    tmp0 = []\n\n    while(now >= 0):\n        if(now == n - 1):\n            if((L & (1 << now))):\n                qc.rz(math.pi * 2, now)\n                #qc.z(now)\n            else:\n                qc.rz(math.pi * 2, now)\n                qc.z(now)\n                tmp0.append(now)\n                qc.x(now)\n        else:\n            if((L & (1 << now))):\n                #qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n            else:\n                qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n\n                tmp0.append(now)\n                qc.x(now)\n\n        now -= 1\n\n\n    for x in tmp0:\n        qc.x(x)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7C88FB86D610", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    now = n - 1\n    tmp0 = []\n\n    while(now >= 0):\n        if(now == n - 1):\n            if((L & (1 << now))):\n                qc.rz(math.pi * 2, now)\n                #qc.z(now)\n            else:\n                qc.rz(math.pi * 2, now)\n                qc.z(now)\n                tmp0.append(now)\n                qc.x(now)\n        else:\n            if((L & (1 << now))):\n                qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n            else:\n                qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n\n                tmp0.append(now)\n                qc.x(now)\n\n        now -= 1\n\n\n    for x in tmp0:\n        qc.x(x)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7C88FB86D610", "submission_order": 4, "result": "WA", "execution_time": "1036 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    now = n - 1\n    tmp0 = []\n\n    while(now >= 0):\n        if(now == n - 1):\n            if((L & (1 << now))):\n                qc.rz(math.pi * 2, now)\n                #qc.z(now)\n            else:\n                qc.rz(math.pi * 2, now)\n                qc.z(now)\n                tmp0.append(now)\n                qc.x(now)\n        else:\n            if((L & (1 << now))):\n                qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n            else:\n                qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n\n                tmp0.append(now)\n                qc.x(now)\n\n        now -= 1\n\n\n    for x in tmp0:\n        qc.x(x)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7C88FB86D610", "submission_order": 5, "result": "WA", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    now = n - 1\n    tmp0 = []\n\n    while(now >= 0):\n        if(now == n - 1):\n            if((L & (1 << now))):\n                qc.rz(math.pi * 2, now)\n                #qc.z(now)\n            else:\n                qc.rz(math.pi * 2, now)\n                qc.z(now)\n                tmp0.append(now)\n                qc.x(now)\n        else:\n            if((L & (1 << now))):\n                qc.crz(math.pi * 2, range(now + 1, n), now)\n                #qc.cz(range(now + 1, n), now)\n            else:\n                qc.crz(math.pi * 2, range(now + 1, n), now)\n                qc.cz(range(now + 1, n), now)\n\n                tmp0.append(now)\n                qc.x(now)\n\n        now -= 1\n\n\n    for x in tmp0:\n        qc.x(x)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7C88FB86D610", "submission_order": 6, "result": "RE", "execution_time": "964 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    now = n - 1\n    tmp0 = []\n\n    while(now >= 0):\n        if(now == n - 1):\n            if((L & (1 << now))):\n                qc.rz(math.pi * 2, now)\n                #qc.z(now)\n            else:\n                qc.rz(math.pi * 2, now)\n                qc.z(now)\n                tmp0.append(now)\n                qc.x(now)\n        else:\n            if((L & (1 << now))):\n                #qc.cz(range(now + 1, n), now)\n                tmp = [i for i in range(now + 1, n)]\n                tmp += [now]\n                qc.append(ZGate().control(n - 1 - now), tmp)\n\n                tmp0.append(now)\n                qc.x(now)\n\n        now -= 1\n\n\n    for x in tmp0:\n        qc.x(x)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7C88FB86D610", "submission_order": 7, "result": "WA", "execution_time": "942 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    now = n - 1\n    tmp0 = []\n\n    while(now >= 0):\n        if(now == n - 1):\n            if((L & (1 << now))):\n                qc.rz(math.pi * 2, now)\n                #qc.z(now)\n            else:\n                qc.rz(math.pi * 2, now)\n                qc.z(now)\n                tmp0.append(now)\n                qc.x(now)\n        else:\n            if((L & (1 << now))):\n                #qc.cz(range(now + 1, n), now)\n                tmp = [i for i in range(now + 1, n)]\n                tmp += [now]\n                qc.append(ZGate().control(n - 1 - now), tmp)\n\n                tmp0.append(now)\n                qc.x(now)\n\n        now -= 1\n\n\n    for x in tmp0:\n        qc.x(x)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7C88FB86D610", "submission_order": 8, "result": "WA", "execution_time": "960 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    now = n - 1\n    tmp0 = []\n\n    while(now >= 0):\n        if(now == n - 1):\n            if((L & (1 << now))):\n                qc.rz(math.pi * 2, now)\n                #qc.z(now)\n            else:\n                qc.rz(math.pi * 2, now)\n                qc.z(now)\n                tmp0.append(now)\n                qc.x(now)\n        else:\n            if((L & (1 << now))):\n                #qc.cz(range(now + 1, n), now)\n                tmp = [i for i in range(now + 1, n)]\n                tmp += [now]\n                qc.append(ZGate().control(n - 1 - now), tmp)\n\n                tmp0.append(now)\n                qc.x(now)\n            else:\n                tmp = [i for i in range(now + 1, n)]\n                tmp += [now]\n                qc.append(ZGate().control(n - 1 - now), tmp)\n\n        now -= 1\n\n\n    for x in tmp0:\n        qc.x(x)\n    \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7E19EE24BD2D", "submission_order": 1, "result": "RE", "execution_time": "1252 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (L):\n        qc.z(int(2/L))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7E19EE24BD2D", "submission_order": 2, "result": "RE", "execution_time": "924 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        if (i%2 == 0):\n            qc.z(int(i/2))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7E19EE24BD2D", "submission_order": 3, "result": "RE", "execution_time": "927 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        if (i%2 == 0):\n            qc.z(int(i/2))\n        if L%2 == 0:\n            qc.z(int(l/2))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7E19EE24BD2D", "submission_order": 4, "result": "RE", "execution_time": "845 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        if (i%2 == 0):\n            qc.z(int(i/2))\n    if L%2 == 0:\n        qc.z(int(l/2))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EE1EBF388C7", "submission_order": 1, "result": "RE", "execution_time": "960 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        controlled_gate = Gate('cz', 2, [])\n        for j in range(n-1):\n            controlled_gate = controlled_gate.control()\n        qc.append(controlled_gate, [i] + list(range(n, n+L)))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n    # Write your code here:\n\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << (n - 1 - j)) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << (n - 1 - j)) == 0:\n                qc.x(qr[j])\n\n    return qc\n\nif __name__ == \"__main__\":\n    c = solve(2, 3)\n    print(c)\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 2, "result": "RE", "execution_time": "1175 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n    # Write your code here:\n\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << (n - 1 - j)) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << (n - 1 - j)) == 0:\n                qc.x(qr[j])\n\n    return qc\n\nif __name__ == \"__main__\":\n    c = solve(2, 3)\n    print(c)\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 3, "result": "RE", "execution_time": "1196 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n    # Write your code here:\n\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << (n - 1 - j)) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << (n - 1 - j)) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 4, "result": "RE", "execution_time": "1062 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n    # Write your code here:\n\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 5, "result": "RE", "execution_time": "1062 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 6, "result": "WA", "execution_time": "976 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 7, "result": "WA", "execution_time": "936 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qr = qc.qregs[0]\n    for i in range(L - 1):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 8, "result": "RE", "execution_time": "872 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << (n - 1 - j)) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << (n - 1 - j)) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 9, "result": "RE", "execution_time": "1112 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 10, "result": "WA", "execution_time": "972 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        # qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 11, "result": "RE", "execution_time": "1051 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            return qc.cz(0, 1)\n        else:\n            assert L == 2\n            return qc\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 12, "result": "WA", "execution_time": "1388 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        return qc\n        if L == 1:\n            return qc.cz(0, 1)\n        else:\n            assert L == 2\n            return qc\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A7EFD2BE29C15", "submission_order": 13, "result": "AC", "execution_time": "2694 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A80C615B0E6E4", "submission_order": 1, "result": "RE", "execution_time": "854 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(XGate().control(n-1),range(L))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A80C615B0E6E4", "submission_order": 2, "result": "RE", "execution_time": "946 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(XGate().control(n-1),range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A811457B856F7", "submission_order": 1, "result": "RE", "execution_time": "945 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate.control(n-1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A811457B856F7", "submission_order": 2, "result": "RE", "execution_time": "866 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate.control(L-1), range(L))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A811457B856F7", "submission_order": 3, "result": "RE", "execution_time": "915 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RXGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(RXGate(2*math.pi).control(n-1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A811457B856F7", "submission_order": 4, "result": "RE", "execution_time": "867 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RXGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(RXGate(2*math.pi).control(n-1), range(L))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A811457B856F7", "submission_order": 5, "result": "RE", "execution_time": "995 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RXGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(RXGate(2*math.pi).control(L-1), range(L))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A811457B856F7", "submission_order": 6, "result": "RE", "execution_time": "979 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RXGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(RXGate(2*math.pi).control(L-1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 1, "result": "RE", "execution_time": "764 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.mcx(qc.qregs[0][:(n-1)],qc.qregs[0][n-1])\n    qc.h(range(n))\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 2, "result": "RE", "execution_time": "852 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(ZGate().control(n - 1), range(n))\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 3, "result": "RE", "execution_time": "856 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(ZGate().control(n - 1), range(n))\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 4, "result": "RE", "execution_time": "1179 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(ZGate().control(n - 1), range(n))\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(ZGate().control(n - 1), range(n))\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 6, "result": "RE", "execution_time": "1016 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(ZGate().control(n - 1), range(n))\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 7, "result": "RE", "execution_time": "1210 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(ZGate().control(n - 1), range(n))\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 8, "result": "RE", "execution_time": "1297 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L, 2**n):\n      stri = bin(i)\n      stri = stri[2:]\n      while len(stri) < n:\n         stri = '0'  + stri   \n      print(stri)\n      for j in range(len(stri)):\n         if stri[j] == '0':\n            qc.x(n-j-1)\n      qc.append(ZGate().control(n - 1), range(n))\n      for j in range(len(stri)):\n         if stri[j] == '0':\n            qc.x(n-j-1)\n         \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 9, "result": "RE", "execution_time": "982 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n != 1:\n      for i in range(L, 2**n):\n         stri = bin(i)\n         stri = stri[2:]\n         while len(stri) < n:\n            stri = '0'  + stri   \n         print(stri)\n         for j in range(len(stri)):\n            if stri[j] == '0':\n               qc.x(n-j-1)\n         qc.append(ZGate().control(n - 1), range(n))\n         for j in range(len(stri)):\n            if stri[j] == '0':\n               qc.x(n-j-1)\n    else:\n       if L == 1:\n          qc.z(1)\n          \n\n         \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 10, "result": "RE", "execution_time": "843 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n != 1:\n      for i in range(L, 2**n):\n         stri = bin(i)\n         stri = stri[2:]\n         while len(stri) < n:\n            stri = '0'  + stri   \n         for j in range(len(stri)):\n            if stri[j] == '0':\n               qc.x(n-j-1)\n         qc.append(ZGate().control(n - 1), range(n))\n         for j in range(len(stri)):\n            if stri[j] == '0':\n               qc.x(n-j-1)\n    else:\n       if L == :\n          qc.z(1)\n          \n\n         \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 11, "result": "RE", "execution_time": "979 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n != 1:\n      for i in range(L, 2**n):\n         stri = bin(i)\n         stri = stri[2:]\n         while len(stri) < n:\n            stri = '0'  + stri   \n         for j in range(len(stri)):\n            if stri[j] == '0':\n               qc.x(n-j-1)\n         qc.append(ZGate().control(n - 1), range(n))\n         for j in range(len(stri)):\n            if stri[j] == '0':\n               qc.x(n-j-1)\n    else:\n       if L == 1:\n          qc.z(1)\n          \n\n         \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A818984145013", "submission_order": 12, "result": "AC", "execution_time": "2407 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n != 1:\n      for i in range(L, 2**n):\n         stri = bin(i)\n         stri = stri[2:]\n         while len(stri) < n:\n            stri = '0'  + stri   \n         for j in range(len(stri)):\n            if stri[j] == '0':\n               qc.x(n-j-1)\n         qc.append(ZGate().control(n - 1), range(n))\n         for j in range(len(stri)):\n            if stri[j] == '0':\n               qc.x(n-j-1)\n    else:\n       if L == 1:\n          qc.z(0)\n          \n\n         \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A86BA66696257", "submission_order": 1, "result": "AC", "execution_time": "1806 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.initialize([0.5,0.5,0.5,0.5])\n\n    # Write your code here:\n    v = 0\n    for i in range(n-1, -1, -1):\n        if (L>>i)&1:\n            for j in range(n-1, i-1, -1):\n                if ((v>>j)&1)==0:\n                    qc.x(j)\n            if i==n-1:\n                qc.z(i)\n            else:\n                qc.h(i)\n                qc.mcx(list(range(i+1, n)), i)\n                qc.h(i)\n            for j in range(n-1, i-1, -1):\n                if ((v>>j)&1)==0:\n                    qc.x(j)\n            v ^= (1<<i)\n    # print(qc.depth())\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(10, 1023)\n    # print(Statevector(qc))\n'''"}
{"problem": "QPC001_B3", "user": "A86E934FD3A80", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n     for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n                \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A86E934FD3A80", "submission_order": 2, "result": "AC", "execution_time": "2790 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n                \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88410F86DDE1", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit.quantum_info.operators import Operator, Pauli\n'''"}
{"problem": "QPC001_B3", "user": "A88410F86DDE1", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import *\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # if L == (1 << n):\n    #   qc.append(GlobalPhaseGate(math.pi))\n    #   return qc\n    # qc.append(ZGate().control(n - 1), range(n))\n    # for i in range(L):\n    #   ..\n    # for i in range(n - 1, -1, -1):\n    #   //\n    s = range(n)\n    f = ZGate().control(n - 1)\n    for i in range(L):\n      for j in range(n):\n        if (i >> j) & 1:\n          continue\n        else:\n          qc.x(j)\n      qc.append(f, s)\n      for j in range(n):\n        if (i >> j) & 1:\n          continue\n        else:\n          qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88410F86DDE1", "submission_order": 3, "result": "RE", "execution_time": "979 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    s = range(n)\n    f = ZGate().control(n - 1)\n    for i in range(L):\n      for j in range(n):\n        if (i >> j) & 1:\n          continue\n        else:\n          qc.x(j)\n      qc.append(f, s)\n      for j in range(n):\n        if (i >> j) & 1:\n          continue\n        else:\n          qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88410F86DDE1", "submission_order": 4, "result": "AC", "execution_time": "2047 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n      if L == 2:\n        qc.z(0)\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      return qc\n\n    s = range(n)\n    f = ZGate().control(n - 1)\n    for i in range(L):\n      for j in range(n):\n        if (i >> j) & 1:\n          continue\n        else:\n          qc.x(j)\n      qc.append(f, s)\n      for j in range(n):\n        if (i >> j) & 1:\n          continue\n        else:\n          qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 1, "result": "RE", "execution_time": "871 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = bin(i)[2:].split(\" \")\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.x(eff_n)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n)\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = bin(i)[2:].split(\" \")\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 2, "result": "WA", "execution_time": "867 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = bin(i)[2:].split(\" \")\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.x(eff_n)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n)\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = bin(i)[2:].split(\" \")\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 3, "result": "WA", "execution_time": "1148 ms", "memory": "92 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = bin(i)[2:].zfill(eff_n).split(\" \")\n            # print(bit_i)\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.x(eff_n)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n)\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = bin(i)[2:].zfill(eff_n).split(\" \")\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 4, "result": "WA", "execution_time": "878 ms", "memory": "90 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = bin(i)[2:].zfill(eff_n).split(\" \")[::-1]\n            # print(bit_i)\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.x(eff_n)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n)\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = bin(i)[2:].zfill(eff_n).split(\" \")[::-1]\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 5, "result": "WA", "execution_time": "1009 ms", "memory": "91 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            # print(bit_i)\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.x(eff_n)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n)\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 6, "result": "WA", "execution_time": "1078 ms", "memory": "91 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            # print(bit_i)\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n            qc.x(eff_n)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n)\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 7, "result": "RE", "execution_time": "1050 ms", "memory": "79 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            # print(bit_i)\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n            qc.x(eff_n + 1)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n + 1)\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 8, "result": "WA", "execution_time": "1029 ms", "memory": "92 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            # print(bit_i)\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n            qc.x(eff_n)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n)\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 9, "result": "RE", "execution_time": "2024 ms", "memory": "94 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if 2 ** (n - 1) > L > 1:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            # print(bit_i)\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n            qc.x(eff_n + 1)\n            qc.append(ZGate().control(n - 1), range(n))\n            qc.x(eff_n + 1)\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n    elif 2 ** (n - 1) < L:\n        eff_n = int(math.log2(L - 1)) + 1\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(eff_n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if j == \"0\":\n                    qc.x(j)\n    else:\n        pass\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 10, "result": "RE", "execution_time": "829 ms", "memory": "79 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bit_i = list(bin(i)[2:].zfill(eff_n))\n        for j, b in enumerate(bit_i):\n            if b == \"1\"\n            qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j, b in enumerate(bit_i):\n            if b == \"1\"\n            qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 11, "result": "RE", "execution_time": "1140 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bit_i = list(bin(i)[2:].zfill(n))\n        for j, b in enumerate(bit_i):\n            if b == \"1\":\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j, b in enumerate(bit_i):\n            if b == \"1\":\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 12, "result": "RE", "execution_time": "1337 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bit_i = list(bin(i)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_i):\n            if b == \"1\":\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j, b in enumerate(bit_i):\n            if b == \"1\":\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 13, "result": "RE", "execution_time": "1327 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bit_i = list(bin(i)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_i):\n            if b == \"0\":\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j, b in enumerate(bit_i):\n            if b == \"0\":\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A88B672F4D436", "submission_order": 14, "result": "AC", "execution_time": "1881 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(L):\n            bit_i = list(bin(i)[2:].zfill(n))[::-1]\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            for j, b in enumerate(bit_i):\n                if b == \"0\":\n                    qc.x(j)\n    else:\n        if L % 2 == 1:\n            qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 1, "result": "RE", "execution_time": "951 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.z(x[i])\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 3, "result": "RE", "execution_time": "849 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.ccz(range(n))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 4, "result": "RE", "execution_time": "848 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.ccz(n,range(n-1))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 6, "result": "RE", "execution_time": "763 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.mcp(nath.pi,range(n-1),n-1)\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 7, "result": "RE", "execution_time": "976 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.mcp(math.pi,range(n-1),n-)\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 8, "result": "RE", "execution_time": "997 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.mcp(math.pi,range(n-1),n-1)\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 9, "result": "RE", "execution_time": "887 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.mcp(math.pi,range(n),n-1)\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 10, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 11, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.append(Gate(Z).control(n - 1), range(n))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 12, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.mcp(math.pi,range(n))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 13, "result": "RE", "execution_time": "874 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n        qc.mcp(math.pi,range(n))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8D2774A1AB1D", "submission_order": 14, "result": "RE", "execution_time": "925 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(math.ceil(math.log2(L))):\n            if i>>j==0:\n                qc.x[j]\n        qc.mcp(math.pi,range(n))\n        for j in range(n):\n            if i>>j==0:\n                qc.x[j]\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8E7F3A9B7344", "submission_order": 1, "result": "WA", "execution_time": "1951 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j]:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.cz(range(i + 1, n), i)\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8E7F3A9B7344", "submission_order": 2, "result": "WA", "execution_time": "1660 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.cz(range(i + 1, n), i)\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A8E7F3A9B7344", "submission_order": 3, "result": "AC", "execution_time": "2068 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A90B3DD8B8852", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n-1),range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A90DE0B5BE2F6", "submission_order": 1, "result": "WA", "execution_time": "893 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A90DE0B5BE2F6", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A90DE0B5BE2F6", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A90DE0B5BE2F6", "submission_order": 4, "result": "AC", "execution_time": "1703 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A916D50E26DFA", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.extensions import ZGate\nfrom qiskit.circuit.library import CU1Gate\nfrom math import pi\nfrom qiskit.quantum_info.operators.operator import Operator\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    unitary = [[0 for _ in range(2**n)] for _ in range(2**n)]\n\n    for i in range(2**n):\n        if i < L:\n            unitary[i][i] = -1\n        else:\n            unitary[i][i] = 1\n\n    oeprator = Operator(unitary)\n\n    qc.append(oeprator, range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A916D50E26DFA", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.quantum_info.operators.operator import Operator\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    unitary = [[0 for _ in range(2**n)] for _ in range(2**n)]\n\n    for i in range(2**n):\n        if i < L:\n            unitary[i][i] = -1\n        else:\n            unitary[i][i] = 1\n\n    oeprator = Operator(unitary)\n\n    qc.append(oeprator, range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A916D50E26DFA", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, CZGate\nfrom math import pi\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n#def solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    dp = [-1 for _ in range(2**n)]\n    for i in range(2**n):\n        if i >= L:\n            if dp[i] == -1:\n                array = []\n                for j in range(n):\n                    if i & (1 << j) != 0:\n                        array.append(j)\n                qc.append(ZGate().control(len(array) - 1), array)\n\n                for j in range(n):\n                    if i & (1 << j) == 0:\n                        dp[i ^ (1 << j)] *= -1\n\n\n\n\n    #qc.append(ZGate(), [1])\n    #qc.append(ZGate().control(1), [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A916D50E26DFA", "submission_order": 4, "result": "RE", "execution_time": "916 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n#def solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    dp = [-1 for _ in range(2**n)]\n    for i in range(2**n):\n        if i >= L:\n            if dp[i] == -1:\n                array = []\n                for j in range(n):\n                    if i & (1 << j) != 0:\n                        array.append(j)\n                qc.append(ZGate().control(len(array) - 1), array)\n\n                for j in range(n):\n                    if i & (1 << j) == 0:\n                        dp[i ^ (1 << j)] *= -1\n\n\n\n\n    #qc.append(ZGate(), [1])\n    #qc.append(ZGate().control(1), [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A916D50E26DFA", "submission_order": 5, "result": "WA", "execution_time": "1130 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n#def solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    dp = [-1 for _ in range(2**n)]\n    for i in range(2**n):\n        if i >= L:\n            if dp[i] == -1:\n                array = []\n                for j in range(n):\n                    if i & (1 << j) != 0:\n                        array.append(j)\n                if len(array) == 1:\n                    qc.z(array[0])\n                else:\n                    qc.append(ZGate().control(len(array) - 1), array)\n\n                for j in range(n):\n                    if i & (1 << j) == 0:\n                        dp[i ^ (1 << j)] *= -1\n\n\n\n\n    #qc.append(ZGate(), [1])\n    #qc.append(ZGate().control(1), [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A916D50E26DFA", "submission_order": 6, "result": "AC", "execution_time": "2501 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n#def solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    dp = [-1 for _ in range(2**n)]\n    for i in range(2**n):\n        if i >= L:\n            if dp[i] == -1:\n                array = []\n                for j in range(n):\n                    if i & (1 << j) != 0:\n                        array.append(j)\n                if len(array) == 1:\n                    qc.z(array[0])\n                else:\n                    qc.append(ZGate().control(len(array) - 1), array)\n                for j in range(2**n):\n                    if j > i:\n                        ok = True\n                        for k in range(n):\n                            if ((i & (1 << k)) != 0) and ((j & (1 << k)) == 0):\n                                ok = False\n                        if ok:\n                            dp[j] *= -1\n\n\n\n\n    #qc.append(ZGate(), [1])\n    #qc.append(ZGate().control(1), [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A91D1964CA146", "submission_order": 1, "result": "RE", "execution_time": "1811 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        for j in range(n):\n            if ((1 << j) & i) == 0:\n                qc.cx(j)\n        qc.append(XGate().control(n-1), range(n-1))\n        \n        for j in range(n):\n            if ((1 << j) & i) == 0:\n                qc.cx(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A91D1964CA146", "submission_order": 2, "result": "AC", "execution_time": "2080 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    if n == 1:\n    \tif L == 2:\n    \t\tqc.x(0)\n    \t\tqc.z(0)\n    \t\tqc.x(0)\n    \t\tqc.z(0)\n    \telse:\n    \t\tqc.x(0)\n    \t\tqc.z(0)\n    \t\tqc.x(0)\n    else:\n\t    for i in range(L):\n\t        for j in range(n):\n\t            if ((1 << j) & i) == 0:\n\t                qc.x(j)\n\t        qc.append(ZGate().control(n-1), range(n))\n\t        \n\t        for j in range(n):\n\t            if ((1 << j) & i) == 0:\n\t                qc.x(j)\n\n    return qc\n\nsolve(2, 1)\n'''"}
{"problem": "QPC001_B3", "user": "A92269224B60F", "submission_order": 1, "result": "RE", "execution_time": "806 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i/(2**j)) % 2 == 0:\n                qc.x(j)\n        qc.cx(range(n),0)\n        for j in range(n):\n            if (i/(2**j)) % 2== 0:\n                qc.x(j)\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A92269224B60F", "submission_order": 2, "result": "RE", "execution_time": "895 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i//(2**j)) % 2 == 0:\n                qc.x(j)\n        qc.append(ZGate().control(n-1),range(n)) \n        for j in range(n):\n            if (i//(2**j)) % 2== 0:\n                qc.x(j)\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A92269224B60F", "submission_order": 3, "result": "WA", "execution_time": "1028 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        return qc\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i//(2**j)) % 2 == 0:\n                qc.x(j)\n        qc.append(ZGate().control(n-1),range(n)) \n        for j in range(n):\n            if (i//(2**j)) % 2== 0:\n                qc.x(j)\n        \n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC001_B3", "user": "A92269224B60F", "submission_order": 4, "result": "AC", "execution_time": "2089 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if L==1:\n            qc.z(0)\n            \n        return qc\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i//(2**j)) % 2 == 0:\n                qc.x(j)\n        qc.append(ZGate().control(n-1),range(n)) \n        for j in range(n):\n            if (i//(2**j)) % 2== 0:\n                qc.x(j)\n        \n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC001_B3", "user": "A976B6792D232", "submission_order": 1, "result": "AC", "execution_time": "1809 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9C4C9B1EB85B", "submission_order": 1, "result": "RE", "execution_time": "1410 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bits = []\n        for bit in range(n):\n            if not ((i >> bit) & 1):\n                bits.append(bit)\n                qc.x(bit)\n            qc.append(ZGate.control(n - 1), range(n))\n        \n        for bit in bits:\n            qc.x(bit)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9C4C9B1EB85B", "submission_order": 2, "result": "RE", "execution_time": "1495 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bits = []\n        for bit in range(n):\n            if not ((i >> bit) & 1):\n                bits.append(bit)\n                qc.x(n - bit - 1)\n            qc.append(ZGate().control(n - 1), range(n))\n        \n        for bit in bits:\n            qc.x(n - bit - 1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9C4C9B1EB85B", "submission_order": 3, "result": "RE", "execution_time": "1350 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bits = []\n        for bit in range(n):\n            if not ((i >> bit) & 1):\n                bits.append(bit)\n                qc.x(bit)\n            qc.append(ZGate().control(n - 1), range(n))\n        \n        for bit in bits:\n            qc.x(bit)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9C4C9B1EB85B", "submission_order": 4, "result": "RE", "execution_time": "1440 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bits = []\n        for bit in range(n):\n            if not ((i >> (n - bit - 1)) & 1):\n                bits.append(bit)\n                qc.x((n - bit - 1))\n            qc.append(ZGate().control(n - 1), range(n))\n        \n        for bit in bits:\n            qc.x(n - bit - 1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9D10C7A3C952", "submission_order": 1, "result": "RE", "execution_time": "787 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j)) <= 0:\n                qc.x(j)\n        qc.mcp(math.pi, list(range(n-1)), n-1)\n        for j in range(n):\n            if (i&(1<<j)) <= 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9D10C7A3C952", "submission_order": 2, "result": "AC", "execution_time": "1208 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1 and L == 1:\n        qc.p(math.pi, 0)\n    if n == 1:\n        return qc\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j)) <= 0:\n                qc.x(j)\n        qc.mcp(math.pi, list(range(n-1)), n-1)\n        for j in range(n):\n            if (i&(1<<j)) <= 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 1, "result": "RE", "execution_time": "849 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nnum_qubits = 3\n\nfor k in range(L):\n    # Get binary representation of the number, padded to the number of qubits\n    binary_rep = format(k, '0' + str(num_qubits) + 'b')\n\n    # List to keep track of which qubits need the X gate (for flipping |1> to |0>)\n    x_gates_needed = []\n\n    for qubit_index, bit in enumerate(reversed(binary_rep)):\n        if bit == '0':\n            # Apply X gate to flip |0> to |1>, if needed\n            qc.x(qubit_index)\n            x_gates_needed.append(qubit_index)\n\n    # Apply controlled Z gate\n    if len(x_gates_needed) < num_qubits:\n        control_qubits = [i for i in range(num_qubits) if i not in x_gates_needed]\n        target_qubit = control_qubits[-1]\n        if len(control_qubits) > 1:\n            qc.h(target_qubit)\n            qc.mct(control_qubits[:-1], target_qubit)  # Multi-controlled Toffoli\n            qc.h(target_qubit)\n        else:\n            # If there is only one control qubit, apply Z gate directly\n            qc.z(target_qubit)\n\n    # Revert the X gates\n    for qubit_index in x_gates_needed:\n        qc.x(qubit_index)\n    \n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 2, "result": "RE", "execution_time": "840 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_qubits = 3\n\n    for k in range(L):\n        binary_rep = format(k, '0' + str(num_qubits) + 'b')\n\n        # List to keep track of which qubits need the X gate (for flipping |1> to |0>)\n        x_gates_needed = []\n\n        for qubit_index, bit in enumerate(reversed(binary_rep)):\n            if bit == '0':\n                # Apply X gate to flip |0> to |1>, if needed\n                qc.x(qubit_index)\n                x_gates_needed.append(qubit_index)\n\n        # Apply controlled Z gate\n        if len(x_gates_needed) < num_qubits:\n            control_qubits = [i for i in range(num_qubits) if i not in x_gates_needed]\n            target_qubit = control_qubits[-1]\n            if len(control_qubits) > 1:\n                qc.h(target_qubit)\n                qc.mct(control_qubits[:-1], target_qubit)  # Multi-controlled Toffoli\n                qc.h(target_qubit)\n            else:\n                # If there is only one control qubit, apply Z gate directly\n                qc.z(target_qubit)\n\n        # Revert the X gates\n        for qubit_index in x_gates_needed:\n            qc.x(qubit_index)\n        \n        qc.barrier()\n        return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 3, "result": "RE", "execution_time": "956 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for k in range(L):\n        binary_rep = format(k, '0' + str(num_qubits) + 'b')\n\n        x_gates_needed = []\n\n        for qubit_index, bit in enumerate(reversed(binary_rep)):\n            if bit == '0':\n                qc.x(qubit_index)\n                x_gates_needed.append(qubit_index)\n\n        if len(x_gates_needed) < num_qubits:\n            control_qubits = [i for i in range(num_qubits) if i not in x_gates_needed]\n            target_qubit = control_qubits[-1]\n            if len(control_qubits) > 1:\n                qc.h(target_qubit)\n                qc.mct(control_qubits[:-1], target_qubit)\n                qc.h(target_qubit)\n            else:\n                qc.z(target_qubit)\n\n        for qubit_index in x_gates_needed:\n            qc.x(qubit_index)\n        \n        # qc.barrier()\n        return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 4, "result": "RE", "execution_time": "829 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\nfor k in range(L):\n    # Get binary representation of the number, padded to the number of qubits\n    binary_rep = format(k, '0' + str(num_qubits) + 'b')\n\n    # List to keep track of which qubits need the X gate (for flipping |1> to |0>)\n    x_gates_needed = []\n\n    for qubit_index, bit in enumerate(reversed(binary_rep)):\n        if bit == '0':\n            # Apply X gate to flip |0> to |1>, if needed\n            qc.x(qubit_index)\n            x_gates_needed.append(qubit_index)\n\n    # Apply controlled Z gate\n    # if len(x_gates_needed) < num_qubits:\n    control_qubits = [i for i in range(num_qubits) if i not in x_gates_needed]\n    print(len(control_qubits))\n    if len(control_qubits) >= 1:\n        qc.append(ZGate().control(len(x_gates_needed)), x_gates_needed+[control_qubits[0]])\n        # qc.h(target_qubit)\n        # qc.mcZ(x_gates_needed, control_qubits[0])  # Multi-controlled Toffoli\n        # qc.h(target_qubit)\n    # else:\n        # If there is only one control qubit, apply Z gate directly\n        # qc.z(target_qubit)\n\n    # # Revert the X gates\n    # for qubit_index in x_gates_needed:\n    #     qc.x(qubit_index)\n    \n    qc.barrier()\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 5, "result": "RE", "execution_time": "817 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\n    for k in range(L):\n        # Get binary representation of the number, padded to the number of qubits\n        binary_rep = format(k, '0' + str(num_qubits) + 'b')\n\n        # List to keep track of which qubits need the X gate (for flipping |1> to |0>)\n        x_gates_needed = []\n\n        for qubit_index, bit in enumerate(reversed(binary_rep)):\n            if bit == '0':\n                # Apply X gate to flip |0> to |1>, if needed\n                qc.x(qubit_index)\n                x_gates_needed.append(qubit_index)\n\n        # Apply controlled Z gate\n        # if len(x_gates_needed) < num_qubits:\n        control_qubits = [i for i in range(num_qubits) if i not in x_gates_needed]\n        print(len(control_qubits))\n        if len(control_qubits) >= 1:\n            qc.append(ZGate().control(len(x_gates_needed)), x_gates_needed+[control_qubits[0]])\n            # qc.h(target_qubit)\n            # qc.mcZ(x_gates_needed, control_qubits[0])  # Multi-controlled Toffoli\n            # qc.h(target_qubit)\n        # else:\n            # If there is only one control qubit, apply Z gate directly\n            # qc.z(target_qubit)\n\n        # # Revert the X gates\n        # for qubit_index in x_gates_needed:\n        #     qc.x(qubit_index)\n        \n        qc.barrier()\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 6, "result": "RE", "execution_time": "924 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\n    for k in range(L):\n        binary_rep = format(k, '0' + str(num_qubits) + 'b')\n\n        x_gates_needed = []\n\n        for qubit_index, bit in enumerate(reversed(binary_rep)):\n            if bit == '0':\n                qc.x(qubit_index)\n                x_gates_needed.append(qubit_index)\n\n        # Apply controlled Z gate\n        control_qubits = [i for i in range(num_qubits) if i not in x_gates_needed]\n        print(len(control_qubits))\n        if len(control_qubits) >= 1:\n            qc.append(ZGate().control(len(x_gates_needed)), x_gates_needed+[control_qubits[0]])\n         \n        qc.barrier()\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 7, "result": "RE", "execution_time": "948 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\n    for k in range(L):\n        binary_rep = format(k, '0' + str(num_qubits) + 'b')\n\n        x_gates_needed = []\n\n        for qubit_index, bit in enumerate(reversed(binary_rep)):\n            if bit == '0':\n                qc.x(qubit_index)\n                x_gates_needed.append(qubit_index)\n\n        # Apply controlled Z gate\n        control_qubits = [i for i in range(num_qubits) if i not in x_gates_needed]\n        print(len(control_qubits))\n        if len(control_qubits) >= 1:\n            qc.append(ZGate().control(len(x_gates_needed)), x_gates_needed+[control_qubits[0]])\n         \n        qc.barrier()\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 8, "result": "RE", "execution_time": "927 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\n    for k in range(L):\n        binary_rep = format(k, '0' + str(n) + 'b')\n\n        x_gates_needed = []\n\n        for qubit_index, bit in enumerate(reversed(binary_rep)):\n            if bit == '0':\n                qc.x(qubit_index)\n                x_gates_needed.append(qubit_index)\n\n        # Apply controlled Z gate\n        control_qubits = [i for i in range(n) if i not in x_gates_needed]\n        print(len(control_qubits))\n        if len(control_qubits) >= 1:\n            qc.append(ZGate().control(len(x_gates_needed)), x_gates_needed+[control_qubits[0]])\n         \n        qc.barrier()\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 9, "result": "WA", "execution_time": "1235 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for k in range(L):\n        binary_rep = format(k, '0' + str(n) + 'b')\n\n        x_gates_needed = []\n\n        for qubit_index, bit in enumerate(reversed(binary_rep)):\n            if bit == '0':\n                qc.x(qubit_index)\n                x_gates_needed.append(qubit_index)\n\n        # Apply controlled Z gate\n        control_qubits = [i for i in range(n) if i not in x_gates_needed]\n        print(len(control_qubits))\n        if len(control_qubits) >= 1:\n            qc.append(ZGate().control(len(x_gates_needed)), x_gates_needed+[control_qubits[0]])\n         \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 10, "result": "RE", "execution_time": "832 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for k in range(L):\n        binary_rep = format(k, '0' + str(n) + 'b')\n\n        x_gates_needed = []\n\n        for qubit_index, bit in enumerate(reversed(binary_rep)):\n            if bit == '0':\n                qc.x(qubit_index)\n                x_gates_needed.append(qubit_index)\n\n        # Apply controlled Z gate\n        control_qubits = [i for i in range(n) if i not in x_gates_needed]\n        print(len(control_qubits))\n        if len(control_qubits) >= 1:\n            qc.append(ZGate().control(len(x_gates_needed)), x_gates_needed+[control_qubits[0]])\n         \n\nreturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 11, "result": "RE", "execution_time": "772 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n         \n\nreturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 12, "result": "RE", "execution_time": "803 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        # if n == 1:\n        #     qc.z(0)\n        # else:\n        #     # apply multiple controlled Z gate\n        #     qc.append(ZGate().control(n - 1), range(n))\n        # for i in range(n):\n        #     if not ((l >> i) & 1):\n        #         qc.x(i)\n         \n\nreturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 13, "result": "RE", "execution_time": "784 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # for l in range(L):\n    #     for i in range(n):\n    #         # check if i-th bit of l is 0 or 1\n    #         if not ((l >> i) & 1):\n    #             qc.x(i)\n        # if n == 1:\n        #     qc.z(0)\n        # else:\n        #     # apply multiple controlled Z gate\n        #     qc.append(ZGate().control(n - 1), range(n))\n        # for i in range(n):\n        #     if not ((l >> i) & 1):\n        #         qc.x(i)\n         \n\nreturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 14, "result": "RE", "execution_time": "889 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # for l in range(L):\n    #     for i in range(n):\n    #         # check if i-th bit of l is 0 or 1\n    #         if not ((l >> i) & 1):\n    #             qc.x(i)\n        # if n == 1:\n        #     qc.z(0)\n        # else:\n        #     # apply multiple controlled Z gate\n        #     qc.append(ZGate().control(n - 1), range(n))\n        # for i in range(n):\n        #     if not ((l >> i) & 1):\n        #         qc.x(i)\n         \n\nreturn qc\n'''"}
{"problem": "QPC001_B3", "user": "A9DF91A7BCC24", "submission_order": 15, "result": "RE", "execution_time": "905 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # for l in range(L):\n    #     for i in range(n):\n    #         # check if i-th bit of l is 0 or 1\n    #         if not ((l >> i) & 1):\n    #             qc.x(i)\n        # if n == 1:\n        #     qc.z(0)\n        # else:\n        #     # apply multiple controlled Z gate\n        #     qc.append(ZGate().control(n - 1), range(n))\n        # for i in range(n):\n        #     if not ((l >> i) & 1):\n        #         qc.x(i)\n         \n\nreturn qc\n'''"}
{"problem": "QPC001_B3", "user": "AA24692EF1DEB", "submission_order": 1, "result": "AC", "execution_time": "1643 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    m = L\n    mbin = []\n    k = m\n    tmp = 0\n    while(tmp < n):\n        mbin = mbin + [k%2]\n        k = k //2\n        tmp += 1\n    if mbin[n-1] == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2, -1, -1):\n        bi = mbin[i]\n        if bi == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            lis = [j for j in range(i+1,n)]\n            qc.mcp(math.pi, lis, i)\n            qc.x(i)\n    for i in range(n):\n        if mbin[i] == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2C9E7244AB2", "submission_order": 1, "result": "RE", "execution_time": "772 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(L):\n    for j in range(n):\n      if ((i >> j) & 1) == 0:\n        qc.x(j)\n    qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n      if ((i >> j) & 1) == 0:\n        qc.x(j)\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2C9E7244AB2", "submission_order": 2, "result": "RE", "execution_time": "989 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(L):\n    for j in range(n):\n      if ((i >> j) & 1) == 0:\n        qc.x(j)\n    qc.mcp(math.pi, range(n - 1), n - 1)\n    for j in range(n):\n      if ((i >> j) & 1) == 0:\n        qc.x(j)\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2C9E7244AB2", "submission_order": 3, "result": "RE", "execution_time": "1033 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(L):\n    for j in range(n):\n      if ((i >> j) & 1) == 0:\n        qc.x(j)\n    qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n      if ((i >> j) & 1) == 0:\n        qc.x(j)\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2C9E7244AB2", "submission_order": 4, "result": "AC", "execution_time": "2780 ms", "memory": "97 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(L):\n    for j in range(n):\n      if ((i >> j) & 1) == 0:\n        qc.x(j)\n    if n == 1:\n      qc.z(0)\n    else:\n      qc.append(ZGate().control(n - 1), range(n))\n    for j in range(n):\n      if ((i >> j) & 1) == 0:\n        qc.x(j)\n  return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2CC3C531AA8", "submission_order": 1, "result": "RE", "execution_time": "952 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.h(i)\n\n    for l in range(L):\n        b = 1\n        for i in range(n):\n            if l & b == 0:\n                qc.x(i)\n            b = b << 1\n        \n        qc.append(ZGate().control(n-1), range(n))\n            \n        b = 1\n        for i in range(n):\n            if l & b == 0:\n                qc.x(i)\n            b = b << 1\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2CC3C531AA8", "submission_order": 2, "result": "RE", "execution_time": "912 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for l in range(L):\n        b = 1\n        for i in range(n):\n            if l & b == 0:\n                qc.x(i)\n            b = b << 1\n        \n        qc.append(ZGate().control(n-1), range(n))\n            \n        b = 1\n        for i in range(n):\n            if l & b == 0:\n                qc.x(i)\n            b = b << 1\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2CC3C531AA8", "submission_order": 3, "result": "RE", "execution_time": "949 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for l in range(L):\n        b = 1\n        for i in range(n):\n            if l & b == 0:\n                qc.x(i)\n            b = b << 1\n        \n        qc.append(ZGate().control(n-1), range(n))\n            \n        b = 1\n        for i in range(n):\n            if l & b == 0:\n                qc.x(i)\n            b = b << 1\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2CC3C531AA8", "submission_order": 4, "result": "WA", "execution_time": "951 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        \n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L == 2:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n\n    else:\n        for l in range(L):\n            b = 1\n            for i in range(n):\n                if l & b == 0:\n                    qc.x(i)\n                b = b << 1\n            \n            qc.append(ZGate().control(n-1), range(n))\n                \n            b = 1\n            for i in range(n):\n                if l & b == 0:\n                    qc.x(i)\n                b = b << 1\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA2CC3C531AA8", "submission_order": 5, "result": "AC", "execution_time": "1821 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n        \n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L == 2:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n\n    else:\n        for l in range(L):\n            b = 1\n            for i in range(n):\n                if l & b == 0:\n                    qc.x(i)\n                b = b << 1\n            \n            qc.append(ZGate().control(n-1), range(n))\n                \n            b = 1\n            for i in range(n):\n                if l & b == 0:\n                    qc.x(i)\n                b = b << 1\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA5715B7D5031", "submission_order": 1, "result": "RE", "execution_time": "1452 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bin_data = format(data, f'0{n}b')        \n        data_0_bits = [i for i, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        qc.x(data_0_bits)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA5715B7D5031", "submission_order": 2, "result": "RE", "execution_time": "1398 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [i for i, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        qc.x(data_0_bits)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        qc.x(data_0_bit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA5715B7D5031", "submission_order": 3, "result": "RE", "execution_time": "1346 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        qc.x(data_0_bits)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA5715B7D5031", "submission_order": 4, "result": "RE", "execution_time": "1503 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [idx for idx, digit in enumerate(bin_data) if digit == '0']\n\n        qc.x(data_0_bits)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA5715B7D5031", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n         if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA5715B7D5031", "submission_order": 6, "result": "RE", "execution_time": "1638 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA5715B7D5031", "submission_order": 7, "result": "AC", "execution_time": "2790 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n        if n>1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA57F006A4F8D", "submission_order": 1, "result": "RE", "execution_time": "977 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def get_indices(m: int):\n        a = []\n        idx = 0\n        while m:\n            if m % 2:\n               a.append(index)\n            index += 1\n            m //= 2\n        return a \n    for i in range(L, 2**n):\n        a = get_indices(i)\n        target = a[-1]\n        controls = a[:-1]\n        qc.h(target); qc.mcx(controls, target); qc.h(target)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA57F006A4F8D", "submission_order": 2, "result": "WA", "execution_time": "988 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def get_indices(m: int):\n        a = []\n        index = 0\n        while m:\n            if m % 2:\n               a.append(index)\n            index += 1\n            m //= 2\n        return a \n    for i in range(L, 2**n):\n        a = get_indices(i)\n        target = a[-1]\n        controls = a[:-1]#; print(target, controls, \"!!!!\")\n        if controls:\n            qc.h(target); qc.mcx(controls, target); qc.h(target)\n        else:\n            qc.z(target)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA57F006A4F8D", "submission_order": 3, "result": "WA", "execution_time": "1086 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    def get_indices(m: int):\n        a = []\n        index = 0\n        while m:\n            if m % 2:\n               a.append(index)\n            index += 1\n            m //= 2\n        return a \n    for i in range(L, 2**n):\n        a = get_indices(i)\n        target = a[-1]\n        controls = a[:-1]#; print(target, controls, \"!!!!\")\n        if controls:\n            qc.h(target); qc.mcx(controls, target); qc.h(target)\n        else:\n            qc.z(target)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA57F006A4F8D", "submission_order": 4, "result": "WA", "execution_time": "1236 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    def xmap(m: int, size: int) -> list[int]:\n         a = []\n         idx = 0\n         while m:\n             if m % 2:\n                 a.append(idx)\n             idx += 1\n             m //= 2\n         return [i for i in range(size) if i not in a]\n    for i in range(L, 2**n):\n        a = xmap(i, n)\n        if a:\n            qc.x(a)\n        if n > 1:\n            qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n        else:\n            qc.z(0)\n        if a:\n            qc.x(a)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA57F006A4F8D", "submission_order": 5, "result": "WA", "execution_time": "1109 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    def xmap(m: int, size: int) -> list[int]:\n         a = []\n         idx = 0\n         while m:\n             if m % 2:\n                 a.append(idx)\n             idx += 1\n             m //= 2\n         return [i for i in range(size) if i not in a]\n    for i in range(L, 2**n):\n        a = xmap(i, n)\n        if a:\n            qc.x(a)\n        if n > 1:\n            qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n        else:\n            qc.z(0)\n        if a:\n            qc.x(a)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA57F006A4F8D", "submission_order": 6, "result": "AC", "execution_time": "2463 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #    qc.h(i)\n    def xmap(m: int, size: int) -> list[int]:\n         a = []\n         idx = 0\n         while m:\n             if m % 2:\n                 a.append(idx)\n             idx += 1\n             m //= 2\n         return [i for i in range(size) if i not in a]\n    for i in range(L, 2**n):\n        a = xmap(i, n)\n        if a:\n            qc.x(a)\n        if n > 1:\n            qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n        else:\n            qc.z(0)\n        if a:\n            qc.x(a)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 1, "result": "RE", "execution_time": "842 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cz(i, 0)  # 制御Zゲートを使用して各状態に -1 をかける\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 2, "result": "RE", "execution_time": "1123 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(CZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 3, "result": "RE", "execution_time": "930 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.append(CZGate(), [i, 0])  # CZゲートを使用して各状態に -1 をかける\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 4, "result": "RE", "execution_time": "802 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Oracleの実装\n    for i in range(L):\n        qc.append(CZGate(), [i, 0])  # CZゲートを使用して各状態に -1 をかける\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 5, "result": "RE", "execution_time": "865 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Oracleの実装\n    for i in range(L):\n        qc.append(CZGate(), [i, 0])  # CZゲートを使用して各状態に -1 をかける\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 6, "result": "RE", "execution_time": "963 ms", "memory": "87 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(CZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 7, "result": "RE", "execution_time": "760 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(CZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 8, "result": "RE", "execution_time": "857 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        qc.append(CZGate(), [i] + list(range(n, n+L)))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 9, "result": "RE", "execution_time": "784 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        qc.append(CZGate(), [i] + list(range(n, n+L)))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 10, "result": "RE", "execution_time": "911 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        qc.append(CZGate(), list(range(n - L, n)) + [i])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 11, "result": "RE", "execution_time": "943 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        qc.append(CZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 12, "result": "RE", "execution_time": "986 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        qc.append(CZGate().control(n - 1), range(n-1))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 13, "result": "RE", "execution_time": "911 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        # i番目のビットを制御ビット、最後のビットをターゲットビットとするCZゲートを追加\n        qc.append(CZGate().control(n - 1), [i] + [n - 1])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 14, "result": "RE", "execution_time": "788 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(2**(n-1)):\n        qc.cz(i, i + 2**(n-1))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 15, "result": "RE", "execution_time": "845 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(2**n):\n        qc.cz(i, (i + 2**(n-1)) % (2**n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 16, "result": "RE", "execution_time": "796 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(CZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA68B1FE361DC", "submission_order": 17, "result": "RE", "execution_time": "768 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(n)\n    for i in range(n):\n        qc.z(n)\n    for i in range(n):\n        qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA6DEFA912962", "submission_order": 1, "result": "RE", "execution_time": "934 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef oracle(qc: QuantumCircuit, n: int, L: int):\n    bits_L = [int(i) for i in bin(L)[2:].zfill(n)][::-1]\n    \n    for i, bit in enumerate(bits_L):\n        if bit == 0:\n            qc.x(i)\n    \n    qc.h(n-1)\n    qc.mct(list(range(n-1)), n-1) \n    qc.h(n-1)\n\n    for i, bit in enumerate(bits_L):\n        if bit == 0:\n            qc.x(i)\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    oracle(qc, n, L)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA6DEFA912962", "submission_order": 2, "result": "RE", "execution_time": "838 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        binary_i = bin(i)[2:].zfill(n)[::-1]\n        for bit_position, bit in enumerate(binary_i):\n            if bit == '0':\n                qc.x(bit_position)\n    multi_control_z = ZGate().control(n)\n    qc.append(multi_control_z, range(n))\n    for bit_position, bit in enumerate(binary_i):\n        if bit == '0':\n            qc.x(bit_position)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA6DEFA912962", "submission_order": 3, "result": "RE", "execution_time": "962 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    binary_L = format(L, f'0{n}b')[::-1]\n    \n    z_gate = ZGate().control(n - 1)\n    control_qubits = [i for i in range(n) if binary_L[i] == '1']\n    if control_qubits:\n        qc.append(z_gate, control_qubits + [n - 1])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA6E41C3AB18F", "submission_order": 1, "result": "AC", "execution_time": "2062 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bitstring = ''\n    controls = []\n    L = 2 ** n - L\n    for i in range(n-1, -1, -1):\n        msb = (L >> i) & 1\n        L = L & (2 ** i - 1)\n        print(i, msb, bitstring, controls)\n        if msb == 1:\n            if not controls:\n                qc.p(pi, i)\n            else:\n                qc.mcp(pi, controls, i, ctrl_state=bitstring)\n        controls.append(i)\n        bitstring = str(1 - msb) + bitstring\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA76A6314CAAE", "submission_order": 1, "result": "RE", "execution_time": "1479 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the Z gate (phase flip) to all states |0⟩, |1⟩, ..., |L-1⟩\n    for i in range(L):\n        binary_repr = f\"{i:0{n}b}\"  # Convert i to binary with n bits\n        controls = [j for j in range(n) if binary_repr[j] == '1']  # Determine which qubits are 1\n        \n        if controls:\n            qc.append(ZGate().control(len(controls)), controls)\n        else:\n            qc.z(0)  # Global phase, ignored in judge\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA76A6314CAAE", "submission_order": 2, "result": "RE", "execution_time": "1283 ms", "memory": "161 MiB", "code": "'''python\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the Z gate (phase flip) to all states |0⟩, |1⟩, ..., |L-1⟩\n    for i in range(L):\n        binary_repr = f\"{i:0{n}b}\"  # Convert i to binary with n bits\n        controls = [j for j in range(n) if binary_repr[j] == '1']  # Determine which qubits are 1\n        \n        if len(controls) == 0:\n            # If no controls (i.e., for |0...0⟩), apply Z to any qubit (global phase, ignored in judge)\n            qc.z(0)\n        elif len(controls) == 1:\n            # If only one control, just apply a Z gate directly\n            qc.z(controls[0])\n        else:\n            # Apply a multi-controlled Z gate\n            qc.append(ZGate().control(len(controls)), controls + [n-1])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA76A6314CAAE", "submission_order": 3, "result": "RE", "execution_time": "1764 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the Z gate (phase flip) to all states |0⟩, |1⟩, ..., |L-1⟩\n    for i in range(L):\n        binary_repr = f\"{i:0{n}b}\"  # Convert i to binary with n bits\n        controls = [j for j in range(n) if binary_repr[j] == '1']  # Determine which qubits are 1\n        \n        if len(controls) == 0:\n            # If no controls (i.e., for |0...0⟩), apply Z to any qubit (global phase, ignored in judge)\n            qc.z(0)\n        elif len(controls) == 1:\n            # If only one control, just apply a Z gate directly\n            qc.z(controls[0])\n        else:\n            # Apply a multi-controlled Z gate\n            qc.append(ZGate().control(len(controls)), controls + [n-1])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA76A6314CAAE", "submission_order": 4, "result": "RE", "execution_time": "1666 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # If L is 0, no operation is needed\n    if L == 0:\n        return qc\n    \n    # Create a multi-controlled Z gate that flips the phase of the first L states\n    # We need to find a way to control the Z gate such that it applies to the first L states\n    # One way is to use a combination of X gates and multi-controlled Z gates\n    \n    # First, find the binary representation of L-1\n    max_state = L - 1\n    binary_max = format(max_state, f'0{n}b')\n    \n    # We will apply X gates to qubits where the corresponding bit in binary_max is 0\n    # This will transform the state |max_state> to |11...1>\n    # Then we can apply a multi-controlled Z gate with all controls being 1\n    \n    # Apply X gates to qubits where the corresponding bit in binary_max is 0\n    for i in range(n):\n        if binary_max[i] == '0':\n            qc.x(i)\n    \n    # Apply a multi-controlled Z gate\n    qc.append(ZGate().control(n-1), range(n))\n    \n    # Apply X gates again to revert the state\n    for i in range(n):\n        if binary_max[i] == '0':\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA76A6314CAAE", "submission_order": 5, "result": "AC", "execution_time": "2100 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # If L == 2^n, then every state gets a -1 overall,\n    # i.e. the oracle is -I which is just a global phase.\n    if L == 2**n:\n        return qc  # global phase ignored\n    \n    # Special case for n == 1.\n    if n == 1:\n        # For one qubit, possible L are 1 or 2.\n        # If L == 1 then only |0> should get a -1.\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n\n    # For n >= 2:\n    # Loop over all integers x such that 0 <= x < L.\n    # For each such x, we want to flip the phase of |x>.\n    for x in range(L):\n        # For each qubit i, if the i-th bit (little–endian) of x is 0,\n        # apply an X gate so that |x> is mapped to |11...1>.\n        for i in range(n):\n            if ((x >> i) & 1) == 0:\n                qc.x(i)\n        # Now, the state corresponding to x has been mapped to |11...1>.\n        # We now flip the phase of |11...1> by applying a multi–controlled Z.\n        # A convenient way is to conjugate a multi–controlled X with H on the target.\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)  # multi–controlled X with controls 0,...,n-2 and target n-1.\n        qc.h(n-1)\n        # Undo the X gates.\n        for i in range(n):\n            if ((x >> i) & 1) == 0:\n                qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA8ECC4E47CDE", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(Gate(z).control(n-1), range(n))\n        for i in range(n):\n            if not ((l>>n)&1):\n                qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA8ECC4E47CDE", "submission_order": 2, "result": "WA", "execution_time": "1214 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l>>n)&1):\n                qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA8ECC4E47CDE", "submission_order": 3, "result": "AC", "execution_time": "2583 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l>>i)&1):\n                qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA9D81B028231", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # L-1 のビット表現を取得し、0のビット位置を特定\n    bits_to_flip = [i for i in range(n) if not ((L - 1) >> i) & 1]\n\n    # 必要なビットを反転\n    for bit in bits_to_flip:\n        qc.x(bit)\n\n    # マルチ制御Zゲートを適用\n    qc.append(ZGate().control(n - 1), range(n))\n\n    # ビットを元に戻す\n    for bit in bits_to_flip:\n        qc.x(bit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA9D81B028231", "submission_order": 2, "result": "RE", "execution_time": "1016 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # L-1 のビット表現を取得し、0のビット位置を特定\n    bits_to_flip = [i for i in range(n) if not ((L - 1) >> i) & 1]\n\n    # 必要なビットを反転\n    for bit in bits_to_flip:\n        qc.x(bit)\n\n    # マルチ制御Zゲートを適用\n    qc.append(ZGate().control(n - 1), range(n))\n\n    # ビットを元に戻す\n    for bit in bits_to_flip:\n        qc.x(bit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA9D81B028231", "submission_order": 3, "result": "RE", "execution_time": "763 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for state in range(L):\n        # Convert the state to binary representation and apply X gates accordingly\n        state_binary = format(state, f'0{n}b')\n        for qubit, bit in enumerate(state_binary):\n            if bit == '0':\n                qc.x(qubit)\n\n        # Apply the controlled Z gate\n        qc.append(ZGate().control(n - 1), range(n))\n\n        # Reapply X gates to revert to the original state\n        for qubit, bit in enumerate(state_binary):\n            if bit == '0':\n                qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA9D81B028231", "submission_order": 4, "result": "RE", "execution_time": "997 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for state in range(L):\n\n        state_binary = format(state, f'0{n}b')[::-1] \n        for qubit, bit in enumerate(state_binary):\n            if bit == '0':\n                qc.x(qubit)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for qubit, bit in enumerate(state_binary):\n            if bit == '0':\n                qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AA9D81B028231", "submission_order": 5, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for state in range(L):\n        state_binary = format(state, f'0{n}b')[::-1]\n        for qubit, bit in enumerate(state_binary):\n            if bit == '0':\n                qc.x(qubit)\n\n        if n > 1:\n            qc.mct(list(range(n - 1)), n - 1) \n        else:\n            qc.z(0) \n\n        for qubit, bit in enumerate(state_binary):\n            if bit == '0':\n                qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAA53FE2DB2FB", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from qiskit.circuit.library import cz\n    qc.append(cz().control(L), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAA89BD1962FB", "submission_order": 1, "result": "RE", "execution_time": "3000 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAA89BD1962FB", "submission_order": 2, "result": "RE", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAA89BD1962FB", "submission_order": 3, "result": "WA", "execution_time": "2172 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAA89BD1962FB", "submission_order": 4, "result": "AC", "execution_time": "2237 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAAB161078B6B", "submission_order": 1, "result": "RE", "execution_time": "1546 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for x in range(L):\n        for i in range(n):\n            if not(x >> i & 1):\n                qc.x(i)\n        if n == 1: qc.z(i)\n        else: qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            if not(x >> i & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAAB161078B6B", "submission_order": 2, "result": "RE", "execution_time": "1904 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for x in range(L):\n        for i in range(n):\n            if not(x >> i & 1):\n                qc.x(i)\n        if n == 1: qc.z(0)\n        else: qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            if not(x >> i & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAAB161078B6B", "submission_order": 3, "result": "AC", "execution_time": "2442 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for x in range(L):\n        for i in range(n):\n            if not(x >> i & 1):\n                qc.x(i)\n        if n == 1: qc.z(0)\n        else: qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            if not(x >> i & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAAB91196FBC8", "submission_order": 1, "result": "RE", "execution_time": "1039 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if l & (1 << i): qc.x(i)\n\n        qc.append(ZGate().control(n - 1), range(n))\n        \n        for i in range(n):\n            if l & (1 << i): qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAAB91196FBC8", "submission_order": 2, "result": "RE", "execution_time": "948 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if (l & (1 << i)) == 0: qc.x(i)\n\n        qc.append(ZGate().control(n - 1), range(n))\n        \n        for i in range(n):\n            if (l & (1 << i)) == 0: qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAAB91196FBC8", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if (l & (1 << i)) == 0: qc.x(i)\n\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        \n        for i in range(n):\n            if (l & (1 << i)) == 0: qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAC2370FA4948", "submission_order": 1, "result": "RE", "execution_time": "826 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n-1),range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAC2370FA4948", "submission_order": 2, "result": "RE", "execution_time": "837 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(Gate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AACE85EC4BBEF", "submission_order": 1, "result": "RE", "execution_time": "2404 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if (L >> i) & 1 == 1:\n            for j in range(i, n):\n                qc.x(j)\n\n            if (n - i == 1):\n                qc.z(i)\n            else:\n                qc.append(ZGate().control(n - i - 1), range(i, n))\n\n            for j in range(i, n):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AACE85EC4BBEF", "submission_order": 2, "result": "RE", "execution_time": "1790 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if (L == pow(2, n)):\n        pass\n    else:\n        for i in range(n):\n            if (L >> i) & 1 == 1:\n                for j in range(i, n):\n                    qc.x(j)\n\n                if (n - i == 1):\n                    qc.z(i)\n                else:\n                    qc.append(ZGate().control(n - i - 1), range(i, n))\n\n                for j in range(i, n):\n                    qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AACE85EC4BBEF", "submission_order": 3, "result": "WA", "execution_time": "1941 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if (L == pow(2, n)):\n        pass\n    else:\n        for i in range(n):\n            if (L >> i) & 1 == 1:\n                for j in range(i, n):\n                    qc.x(j)\n\n                if (n - i == 1):\n                    qc.z(i)\n                else:\n                    qc.append(ZGate().control(n - i - 1), range(i, n))\n\n                for j in range(i, n):\n                    qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AACE85EC4BBEF", "submission_order": 4, "result": "AC", "execution_time": "2960 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if (L >> i) & 1 == 0: # l_i is 0; condition for (m_i < l_i)\n            continue\n        else: # l_i = 1 & m_i = 0 ; l_i = m_i = 1 case is eliminated at previous step\n            for j in range(i+1, n):\n                if (L >> j) & 1 == 0:\n                    qc.x(j)\n                \n            qc.x(i)\n\n            if (i == n - 1):\n                qc.z(i)\n            else:\n                qc.append(ZGate().control(n - i - 1), range(i, n))\n            \n            qc.x(i)\n\n            for j in range(i+1, n):\n                if (L >> j) & 1 == 0:\n                    qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"b\"))))\n        for k in range(b.len()):\n            if b[k] == 0:\n                qc.x(k)\n        qc.append(ZGate().control(n-1), range(n))\n        for k in range(b.len()):\n            if b[k] == 0:\n                qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 2, "result": "RE", "execution_time": "794 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"b\"))))\n        for k in range(b.len()):\n            if b[k] == 0:\n                qc.x(k)\n        qc.append(ZGate().control(n-1), range(n))\n        for k in range(b.len()):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 3, "result": "RE", "execution_time": "776 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"b\"))))\n        for k in range(b.len()):\n            if b[k] == 0:\n                qc.x(k)\n        qc.append(ZGate().control(n-1), range(n))\n        for k in range(b.len()):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 4, "result": "RE", "execution_time": "933 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"b\"))))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n        qc.append(ZGate().control(n-1), range(n))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 5, "result": "RE", "execution_time": "1088 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"b\"))))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n        qc.append(ZGate().control(n-1), range(n))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 6, "result": "RE", "execution_time": "804 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"b\"))))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n        qc.append(ZGate().control(n-1), range(n))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 7, "result": "RE", "execution_time": "1300 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(min(L, 2**n)):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"b\"))))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n        qc.append(ZGate().control(n-1), range(n))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 8, "result": "RE", "execution_time": "869 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"0\"+str(n)+\"b\"))))\n        print(b)\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n        qc.append(ZGate().control(n-1), range(n))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 9, "result": "WA", "execution_time": "978 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"0\"+str(n)+\"b\"))))\n        print(b)\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 10, "result": "WA", "execution_time": "1112 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"0\"+str(n)+\"b\"))))\n        print(b)\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 11, "result": "WA", "execution_time": "961 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"0\"+str(n)+\"b\"))))\n        print(b)\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for k in range(len(b)):\n            if b[k] == 0:\n                qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AAF87050F5BF4", "submission_order": 12, "result": "AC", "execution_time": "2278 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # for i in range(n):\n    #     qc.h(i)\n\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"0\"+str(n)+\"b\"))))\n        print(b)\n        for k in range(n):\n            if b[k] == 0:\n                qc.x(n-k-1)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for k in range(n):\n            if b[k] == 0:\n                qc.x(n-k-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB1C9F88C4B92", "submission_order": 1, "result": "RE", "execution_time": "2023 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # qc.append(XGate().control(n), 0)\n    for i in range(L-1):\n        # qc.z(0)\n        qc.append(ZGate().control(n-1), range(n))\n    qc.draw()\n    print(qc)\n\n    return qc\nsolve(5,4)\n'''"}
{"problem": "QPC001_B3", "user": "AB1C9F88C4B92", "submission_order": 2, "result": "WA", "execution_time": "1867 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # qc.append(XGate().control(n), 0)\n    if (n>1):\n        for i in range(L-1):\n            # qc.z(0)\n            qc.append(ZGate().control(n-1), range(n))\n        qc.draw()\n        print(qc)\n    else:\n        for i in range(L-1):\n            qc.z(i)\n\n    return qc\nsolve(5,4)\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 1, "result": "RE", "execution_time": "874 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    arr = [i for i in range(n - 1)]\n    for i in range(n):\n        qc.h(i)\n        \n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n        qc.h(n - 1)\n        qc.mct(arr, n - 1)\n        qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n    # qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 2, "result": "RE", "execution_time": "951 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    arr = [i for i in range(n - 1)]\n    for i in range(n):\n        qc.h(i)\n        \n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n        qc.h(n - 1)\n        qc.mcx(arr, n - 1)\n        qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n    # qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 3, "result": "RE", "execution_time": "924 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n#     arr = [i for i in range(n - 1)]\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n#         qc.h(n - 1)\n#         qc.mcx(list(range(n - 1)), n - 1)\n#         qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n                \n    #qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 4, "result": "RE", "execution_time": "965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n#     arr = [i for i in range(n - 1)]\n    from qiskit.circuit.library import ZGate\n    \n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(n - 1 - j)\n        qc.append(ZGate().control(n - 1), range(n))\n#         qc.h(n - 1)\n#         qc.mcx(list(range(n - 1)), n - 1)\n#         qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(n - 1 - j)\n                \n    #qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 5, "result": "RE", "execution_time": "1204 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, RZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n#     arr = [i for i in range(n - 1)]\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n        qc.append(RZGate(math.pi * 2).control(n - 1), range(n))\n#         qc.h(n - 1)\n#         qc.mcx(list(range(n - 1)), n - 1)\n#         qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n                \n    #qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 6, "result": "WA", "execution_time": "1026 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, RZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n#     arr = [i for i in range(n - 1)]\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n        # qc.append(RZGate(math.pi * 2).control(n - 1), range(n))\n#         qc.h(n - 1)\n#         qc.mcx(list(range(n - 1)), n - 1)\n#         qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n                \n    #qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 7, "result": "WA", "execution_time": "903 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, RZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n#     arr = [i for i in range(n - 1)]\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n#         qc.h(n - 1)\n#         qc.mcx(list(range(n - 1)), n - 1)\n#         qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n                \n    #qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 8, "result": "RE", "execution_time": "1175 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n#     arr = [i for i in range(n - 1)]\n    # for i in range(n):\n    #     qc.h(i)\n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n#         qc.h(n - 1)\n#         qc.mcx(list(range(n - 1)), n - 1)\n#         qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n                \n    #qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB20C4B99EBAB", "submission_order": 9, "result": "AC", "execution_time": "2246 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n#     arr = [i for i in range(n - 1)]\n    # for i in range(n):\n    #     qc.h(i)\n    for i in range(L):\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n        if n == 1: qc.z(0)\n        else: qc.append(ZGate().control(n - 1), range(n))\n#         qc.h(n - 1)\n#         qc.mcx(list(range(n - 1)), n - 1)\n#         qc.h(n - 1)\n        for j in range(n):\n            if i >> j & 1: continue\n            qc.x(j)\n                \n    #qc.append()\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB2B8D99C3C9E", "submission_order": 1, "result": "RE", "execution_time": "2526 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RXGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.rx(2*np.pi,0)\n    rx_gate = RXGate(2*np.pi)\n    mc_rx = rx_gate.control(n - 1)\n    qc.append(mc_rx, qargs=range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB2B8D99C3C9E", "submission_order": 2, "result": "RE", "execution_time": "1942 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RXGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.rx(2*math.pi,0)\n    rx_gate = RXGate(2*math.pi)\n    mc_rx = rx_gate.control(n - 1)\n    qc.append(mc_rx, qargs=range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB2B8D99C3C9E", "submission_order": 3, "result": "WA", "execution_time": "2246 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_code = format(L, f'0{n}b')\n    for i in range(n):\n        if L_code[i] == \"1\":\n            for j in range(i):\n                if L_code[j] == \"0\":\n                    qc.x(n-j-1)\n            qc.x(n-i-1)\n            if i == 0:\n                qc.z(n-1)\n            else:\n                qc.append(ZGate().control(i), qargs=range(n-1,n-i-2,-1))\n            for j in range(i):\n                if L_code[j] == \"0\":\n                    qc.x(n-j-1)\n            qc.x(n-i-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB2B8D99C3C9E", "submission_order": 4, "result": "AC", "execution_time": "2445 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 2**n:\n      qc.rx(2*math.pi,0)\n    else:\n      L_code = format(L, f'0{n}b')\n      for i in range(n):\n          if L_code[i] == \"1\":\n              for j in range(i):\n                  if L_code[j] == \"0\":\n                      qc.x(n-j-1)\n              qc.x(n-i-1)\n              if i == 0:\n                  qc.z(n-1)\n              else:\n                  qc.append(ZGate().control(i), qargs=range(n-1,n-i-2,-1))\n              for j in range(i):\n                  if L_code[j] == \"0\":\n                      qc.x(n-j-1)\n              qc.x(n-i-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB2E0B0BBEE73", "submission_order": 1, "result": "WA", "execution_time": "997 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        # print(l)\n        # i=0\n        for i in range(n):\n            if not (1<<i)&l:\n                qc.x(n-i-1)\n                # print(\"i=\",i)\n        if n>1:\n            qc.h(0)\n            qc.mcx(list(range(1,n)),0)\n            qc.h(0)\n        else:\n            qc.z(0)\n        \n        for i in range(n):\n            if not (1<<i)&l:\n                qc.x(n-i-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB2E0B0BBEE73", "submission_order": 2, "result": "AC", "execution_time": "1920 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        # print(l)\n        # i=0\n        for i in range(n):\n            if not (1<<i)&l:\n                qc.x(i)\n                # print(\"i=\",i)\n        if n>1:\n            qc.h(0)\n            qc.mcx(list(range(1,n)),0)\n            qc.h(0)\n        else:\n            qc.z(0)\n        \n        for i in range(n):\n            if not (1<<i)&l:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 1, "result": "RE", "execution_time": "1228 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(L):\n        binary_str = format(i, f'0{n}b')\n    \n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n        \n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n        \n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 2, "result": "RE", "execution_time": "1938 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(L):\n        binary_str = format(i, f'0{n}b')\n    \n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n        \n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 3, "result": "RE", "execution_time": "1424 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(L):\n\n        for qubit_index in range(n):\n            if not (i & (1 << qubit_index)):\n                qc.x(qubit_index)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n        \n        for qubit_index in range(n):\n            if not (i & (1 << qubit_index)):\n                qc.x(qubit_index)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 4, "result": "RE", "execution_time": "1622 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(L):\n\n        binary_str = format(i, f'0{n}b')\n\n        for qubit_index, bit in enumerate(binary_str[::-1]):\n            if bit == '0':\n                qc.x(qubit_index)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n        \n        for qubit_index, bit in enumerate(binary_str[::-1]):\n            if bit == '0':\n                qc.x(qubit_index)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 5, "result": "RE", "execution_time": "1327 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(L):\n\n        binary_str = format(i, f'0{n}b')\n\n        for qubit_index, bit in enumerate(binary_str[::-1]):\n            if bit == '0':\n                qc.x(qubit_index)\n        \n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n        \n        for qubit_index, bit in enumerate(binary_str[::-1]):\n            if bit == '0':\n                qc.x(qubit_index)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 6, "result": "RE", "execution_time": "1823 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(L):\n\n        binary_str = format(i, f'0{n}b')\n\n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n        \n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1) \n        qc.h(n-1)\n        \n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 7, "result": "RE", "execution_time": "1761 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(L):\n\n        binary_str = format(i, f'0{n}b')\n\n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n        \n        #qc.h(n-1)\n        #qc.mcx(list(range(n-1)), n-1) \n        #qc.h(n-1)\n        qc.append(ZGate().control(n - 1), range(n))\n        \n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 8, "result": "RE", "execution_time": "1979 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #qc.h(range(n))\n\n    for i in range(L):\n\n        binary_str = format(i, f'0{n}b')\n\n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n        \n        #qc.h(n-1)\n        #qc.mcx(list(range(n-1)), n-1) \n        #qc.h(n-1)\n        qc.append(ZGate().control(n - 1), range(n))\n        \n        for qubit_index, bit in enumerate(binary_str):\n            if bit == '0':\n                qc.x(qubit_index)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 9, "result": "RE", "execution_time": "1566 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        for j in range(n):\n            if (1 << j) & i == 0:\n                qc.x(j)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        for j in range(n):\n            if (1 << j) & i == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB59C126C1BFE", "submission_order": 10, "result": "AC", "execution_time": "2803 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        for j in range(n):\n            if (1 << j) & i == 0:\n                qc.x(j)\n\n        if n > 1:\n            qc.append(ZGate().control(n - 1), range(n))\n        else:\n            qc.z(0)\n\n        for j in range(n):\n            if (1 << j) & i == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB5F2E90F96D3", "submission_order": 1, "result": "RE", "execution_time": "1353 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n\n    # 全部1になっている物を反転\n    def reverse(qubits,qc):\n        qc.append(ZGate().control(qubits - 1), range(qubits))\n    \n    # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    to_calcable(n,qc,0)\n    reverse(n,qc)\n    to_calcable(n,qc,0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB5F2E90F96D3", "submission_order": 2, "result": "RE", "execution_time": "1306 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n\n    # 全部1になっている物を反転\n    def reverse(qubits,qc):\n        qc.append(ZGate().control(qubits - 1), range(qubits))\n    \n    # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    for i in range(L):\n        to_calcable(n,qc,i)\n        reverse(n,qc)\n        to_calcable(n,qc,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB5F2E90F96D3", "submission_order": 3, "result": "AC", "execution_time": "2784 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n\n    # 全部1になっている物を反転\n    def reverse(qubits,qc):\n        if qubits>1:\n            qc.append(ZGate().control(qubits - 1), range(qubits))\n        else:\n            qc.z(0)\n    \n    # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    for i in range(L):\n        to_calcable(n,qc,i)\n        reverse(n,qc)\n        to_calcable(n,qc,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 1, "result": "RE", "execution_time": "908 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(i <= L):\n        \n        else:\n            bit = char(bin(i))\n            char = str(bin(4))[2:]\n            positions = [pos for pos, char in enumerate(reversed(binary_string)) if char == '1']\n            qc.z(positions[0])\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 2, "result": "RE", "execution_time": "908 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(i > L):\n            bit = char(bin(i))\n            char = str(bin(4))[2:]\n            positions = [pos for pos, char in enumerate(reversed(binary_string)) if char == '1']\n            qc.z(positions[0])\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 3, "result": "WA", "execution_time": "1033 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(i > L):\n            # 例えば、i = 3 の場合\n\n            # i を2進数文字列に変換し、'0b' プレフィックスを削除\n            binary_string = bin(i)[2:]\n\n            # 1のビットが存在する位置を見つける\n            for j in range(len(binary_string)):\n                if(binary_string[j] == '1'):\n                    # 1のビットが存在する位置に対応する量子ビットにCNOTゲートを適用\n                    print(j)\n                    qc.z(j)\n                    break\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 4, "result": "WA", "execution_time": "1009 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(i > L):\n            # 例えば、i = 3 の場合\n\n            # i を2進数文字列に変換し、'0b' プレフィックスを削除\n            binary_string = bin(i)[2:]\n\n            # 1のビットが存在する位置を見つける\n            for j in range(len(binary_string)):\n                if(binary_string[j] == '1'):\n                    # 1のビットが存在する位置に対応する量子ビットにCNOTゲートを適用\n                    qc.z(j)\n                    break\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 5, "result": "WA", "execution_time": "899 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(i > L):\n            # 例えば、i = 3 の場合\n\n            # i を2進数文字列に変換し、'0b' プレフィックスを削除\n            binary_string = bin(i)[2:]\n\n            # 1のビットが存在する位置を見つける\n            for j in range(len(binary_string)):\n                if(binary_string[j] == '1'):\n                    # 1のビットが存在する位置に対応する量子ビットにCNOTゲートを適用\n                    j = len(binary_string) - j\n                    qc.z(j)\n                    break\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 6, "result": "RE", "execution_time": "892 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(2**n):\n        if(i > L):\n            # 例えば、i = 3 の場合\n\n            # i を2進数文字列に変換し、'0b' プレフィックスを削除\n            binary_string = bin(i)[2:]\n\n            # 1のビットが存在する位置を見つける\n            for j in range(len(binary_string)):\n                if(binary_string[j] == '1'):\n                    # 1のビットが存在する位置に対応する量子ビットにCNOTゲートを適用\n                    j = len(binary_string) - \n                    qc.z(j)\n                    break\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 7, "result": "RE", "execution_time": "907 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gat\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_qubits = n\n    for i in range(L):\n    state = format(i, '0' + str(num_qubits) + 'b')\n    qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n    qc.append(ZGate().control(num_qubits-1), qc.qubits)\n    qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 8, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gat\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_qubits = n\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 9, "result": "RE", "execution_time": "886 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_qubits = n\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 10, "result": "RE", "execution_time": "928 ms", "memory": "87 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_qubits = n\n    for i in range(n**2):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB61C0E89E4C9", "submission_order": 11, "result": "AC", "execution_time": "2843 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    # 必要な量子ビットの数を計算\n    num_qubits = max(n, math.ceil(math.log2(L+1)))\n    qc = QuantumCircuit(num_qubits)\n\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            # 1量子ビットの場合、通常のZゲートを使用\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB75271E24250", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import Aer, execute, QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import MCPhaseGate, ZGate\n \ndef mex(lis):\n    for num in range(100):\n        if num not in lis:\n            # print(num,flush=True)\n            return num\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    D=[0 for i in range(2**n)]\n    for i in range(L , 2**n):\n        if D[i]==0:\n            sub = []\n            for q in range(n):\n                if i>>q&1:\n                    sub.append(q)\n            \n            num_ctrl_qubits = sub\n            # MCPhaseGate(ZGate(), num_ctrl_qubits/\n            # MCPhaseGate()\n            # qc.append(ZGate().control(len(sub)-1), sub)\n            \n            tgt = mex(sub)\n            qc.mcp(-1,sub,tgt)\n            \n            # print(sub)\n            for num in range(i,2**n):\n                j = num&i==i\n                if j:\n                    D[num]^=1\n            # print(D)\n    \n    # print(D)\n\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB75271E24250", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import Aer, execute, QuantumCircuit, QuantumRegister\n \ndef mex(lis):\n    for num in range(100):\n        if num not in lis:\n            # print(num,flush=True)\n            return num\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    D=[0 for i in range(2**n)]\n    for i in range(L , 2**n):\n        if D[i]==0:\n            sub = []\n            for q in range(n):\n                if i>>q&1:\n                    sub.append(q)\n            \n            num_ctrl_qubits = sub\n            # MCPhaseGate(ZGate(), num_ctrl_qubits/\n            # MCPhaseGate()\n            # qc.append(ZGate().control(len(sub)-1), sub)\n            \n            tgt = mex(sub)\n            qc.mcp(-1,sub,tgt)\n            \n            # print(sub)\n            for num in range(i,2**n):\n                j = num&i==i\n                if j:\n                    D[num]^=1\n            # print(D)\n    \n    # print(D)\n\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB75271E24250", "submission_order": 3, "result": "RE", "execution_time": "832 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \ndef mex(lis):\n    for num in range(100):\n        if num not in lis:\n            # print(num,flush=True)\n            return num\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    D=[0 for i in range(2**n)]\n    for i in range(L , 2**n):\n        if D[i]==0:\n            sub = []\n            for q in range(n):\n                if i>>q&1:\n                    sub.append(q)\n            \n            num_ctrl_qubits = sub\n            # MCPhaseGate(ZGate(), num_ctrl_qubits/\n            # MCPhaseGate()\n            # qc.append(ZGate().control(len(sub)-1), sub)\n            \n            tgt = mex(sub)\n            qc.mcp(-1,sub,tgt)\n            \n            # print(sub)\n            for num in range(i,2**n):\n                j = num&i==i\n                if j:\n                    D[num]^=1\n            # print(D)\n    \n    # print(D)\n\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 1, "result": "RE", "execution_time": "1127 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(XGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 2, "result": "RE", "execution_time": "893 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 3, "result": "RE", "execution_time": "1277 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 4, "result": "RE", "execution_time": "977 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(L))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 5, "result": "RE", "execution_time": "1001 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(0), range(L))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 6, "result": "RE", "execution_time": "1103 ms", "memory": "87 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,L):\n        qc.append(ZGate().control(n), i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 7, "result": "RE", "execution_time": "829 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,L):\n        qc.append(ZGate().control(i), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 8, "result": "RE", "execution_time": "1095 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,L):\n        qc.append(ZGate().control(1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 9, "result": "RE", "execution_time": "817 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,L):\n        qc.append(ZGate().control(i), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB87CA748E006", "submission_order": 10, "result": "AC", "execution_time": "2106 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    A = []\n    B = [1] * (2 ** n) \n    for i in range(2**n):\n      A += [(i.bit_count(),i)]\n    A.sort()\n    for (_,i) in A:\n      tgt = -1\n      if i < L:\n        tgt = 1\n      if tgt != B[i]:\n        l = []\n        for b in range(n):\n          if (i & (1 << b)) > 0:\n            l += [b]\n        if len(l) == 1:\n          qc.z(l[0])\n        else:\n          qc.append(ZGate().control(len(l) - 1), l)\n        for b in range(2**n):\n          if (i & b) == i:\n            B[b] *= -1\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB9A98281ECB3", "submission_order": 1, "result": "WA", "execution_time": "834 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.y(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AB9A98281ECB3", "submission_order": 2, "result": "WA", "execution_time": "995 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 1, "result": "RE", "execution_time": "1633 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l_bit_str = bin(L)[1:]\n\n    b_n_1 = l_bit_str[0]\n    if b_n_1 == \"0\":\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1, -1):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.mcx(range(n-1, i, 1), i)\n            qc.x(i)\n\n    for i in range(n):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 2, "result": "RE", "execution_time": "1416 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l_bit_str = bin(L)[1:]\n\n    b_n_1 = l_bit_str[0]\n    if b_n_1 == \"0\":\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1, -1):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.append(ZGate().control(i - 1), range(i))\n            qc.x(i)\n\n    for i in range(n):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 3, "result": "RE", "execution_time": "1498 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l_bit_str = bin(L)[2:]\n    print(l_bit_str)\n\n    b_n_1 = l_bit_str[0]\n    if b_n_1 == \"0\":\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    # print(n-1, b_n_1)\n    # print(qc.draw())\n    for i in range(n-2, -1, -1):\n        b_i = l_bit_str[n - i -1]\n        if b_i == \"0\":\n            qc.x(i)\n        else:\n            qc.x(i)\n            c_bits = list(range(i + 1, n))\n            qc.mcx(c_bits, i)\n            qc.x(i)\n\n        # print(i, b_i)\n        # print(qc.draw())\n\n    for i in range(1, n):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 4, "result": "RE", "execution_time": "1394 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l_bit_str = bin(L)[2:]\n    print(l_bit_str)\n\n    b_n_1 = l_bit_str[0]\n    if b_n_1 == \"0\":\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    # print(n-1, b_n_1)\n    # print(qc.draw())\n    for i in range(n-2, -1, -1):\n        b_i = l_bit_str[n - i -1]\n        if b_i == \"0\":\n            qc.x(i)\n        else:\n            qc.x(i)\n            c_bits = list(range(i + 1, n))\n            qc.mcx(c_bits, i)\n            qc.x(i)\n\n        # print(i, b_i)\n        # print(qc.draw())\n\n    for i in range(1, n):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(n-i-1)\n\n    return qc.reverse_bits()\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 5, "result": "RE", "execution_time": "1477 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l_bit_str = bin(L)[2:]\n    print(l_bit_str)\n\n    b_n_1 = l_bit_str[0]\n    if b_n_1 == \"0\":\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    # print(n-1, b_n_1)\n    # print(qc.draw())\n    qc.barrier()\n    for i in range(n-2, -1, -1):\n        b_i = l_bit_str[n - i -1]\n        if b_i == \"0\":\n            qc.x(i)\n        else:\n            qc.x(i)\n            qubits = list(range(i, n))\n            qc.append(ZGate().control(n - i - 1), qubits)\n            qc.x(i)\n\n        # print(i, b_i)\n        # print(qc.draw())\n        qc.barrier() \n    for i in range(1, n):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(n-i-1)\n        qc.barrier() \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 6, "result": "RE", "execution_time": "1396 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l_bit_str = bin(L)[2:]\n    print(l_bit_str)\n\n    b_n_1 = l_bit_str[0]\n    if b_n_1 == \"0\":\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    # print(n-1, b_n_1)\n    # print(qc.draw())\n    qc.barrier()\n    for i in range(n-2, -1, -1):\n        b_i = l_bit_str[n - i -1]\n        if b_i == \"0\":\n            qc.x(i)\n        else:\n            qc.x(i)\n            qubits = list(range(i, n))\n            qc.append(ZGate().control(n - i - 1), qubits)\n            qc.x(i)\n\n        # print(i, b_i)\n        # print(qc.draw())\n        qc.barrier() \n    for i in range(1, n):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(n-i-1)\n        qc.barrier() \n\n    return qc.reverse_bits()\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 7, "result": "RE", "execution_time": "1558 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l_bit_str = np.binary_repr(L, n)\n    # print(l_bit_str)\n\n    b_n_1 = l_bit_str[0]\n    if b_n_1 == \"0\":\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    # print(n-1, b_n_1)\n    # print(qc.draw())\n    qc.barrier()\n    for i in range(n-2, -1, -1):\n        b_i = l_bit_str[n - i -1]\n        if b_i == \"0\":\n            qc.x(i)\n        else:\n            qc.x(i)\n            qubits = list(range(i, n))\n            qc.append(ZGate().control(n - i - 1), qubits)\n            qc.x(i)\n\n        qc.barrier() \n    for i in range(1, n):\n        b_i = l_bit_str[i]\n        if b_i == \"0\":\n            qc.x(n-i-1)\n        qc.barrier() \n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 8, "result": "RE", "execution_time": "1290 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    # Write your code here:\n    v = np.array([-1] * n + [1]*(L-n))\n    matrix = np.diag(v)\n\n    qc.append(UnitaryGate(matrix), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 9, "result": "RE", "execution_time": "1348 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    # Write your code here:\n    v = np.array([-1] * n + [1]* (n - L))\n    matrix = np.diag(v)\n\n    qc.append(UnitaryGate(matrix), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 10, "result": "RE", "execution_time": "1341 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    # Write your code here:\n    v = np.array([-1] * L + [1]* (n - L))\n    matrix = np.diag(v)\n\n    qc.append(UnitaryGate(matrix), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 11, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    # Write your code here:\n    v = np.array([-1] * L + [1]* (2**n - L))\n    matrix = np.diag(v)\n\n    qc.append(UnitaryGate(matrix), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA0768B0067E", "submission_order": 12, "result": "RE", "execution_time": "1380 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    # Write your code here:\n    num_binary = np.binary_repr(L, n)\n    \n    # Discard the 0s at the end, as they will not be used and save\n    # unnecessary X gates\n    num_binary = num_binary.rstrip('0')\n\n    if num_binary[0] == '1':\n        qc.x(n - 1)\n        qc.z(n - 1)\n        qc.x(n - 1)\n    else:\n        qc.x(n - 1)\n    \n    # For loop on the remaining digits\n    for position1, value in enumerate(num_binary[1:]):\n        # Rename the position as it starts with 0 in the second bit and\n        # we want it to be 1.\n        position = position1 + 1\n\n        if value == '0':\n            qc.x(n - position - 1)\n        else:\n            qc.x(n - position-1)\n            qubits = list(range(n-1, n-position-2, - 1))\n            qc.append(ZGate().control(position), qubits)\n            qc.x(n-position-1)\n    \n    for position, value in enumerate(num_binary):\n        # Apply X gates to qubits in position of bits with a 0 value\n        if value == '0':\n            qc.x(n-position-1)\n        else:\n            pass\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA820059A6BA", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((l >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.z(0)\n    else:\n        # apply multiple controlled Z gate\n        qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA820059A6BA", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n        for l in range(L):\n                for i in range(n):\n                    # check if i-th bit of l is 0 or 1\n                    if not ((l >> i) & 1):\n                        qc.x(i)\n                if n == 1:\n                    qc.z(0)\n                else:\n                    # apply multiple controlled Z gate\n                    qc.append(ZGate().control(n - 1), range(n))\n                for i in range(n):\n                    if not ((l >> i) & 1):\n                        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA820059A6BA", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n   for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n                \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABA820059A6BA", "submission_order": 4, "result": "AC", "execution_time": "2295 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABC449A983B9F", "submission_order": 1, "result": "RE", "execution_time": "1313 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    cnz = ZGate().control(n - 1)\n    skip_idx = []\n    first = [True for _ in range(n)]\n    for d in reversed(range(n)):\n        if (L>>d)&1:\n            flip = L&(((1<<n)-1)-((1<<d)-1))\n            if d > 0:\n                flip -= 1\n            for i in range(n):\n                if (not (i in skip_idx) or first[i]) and ((flip>>i)&1) == 0:\n                    qc.x(i)\n                    first[i] = False\n            qc.append(cnz, range(n))\n            for i in range(n):\n                if (not (i in skip_idx) or first[i]) and ((flip>>i)&1) == 0:\n                    qc.x(i)\n                    first[i] = False\n        else:\n            skip_idx.append(d)\n            \n    for i in skip_idx:\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABC449A983B9F", "submission_order": 2, "result": "AC", "execution_time": "1233 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for d in reversed(range(n)):\n        if (L>>d)&1:\n            flip = (L>>d)-1\n            for i in range(n-d):\n                if ((flip>>i)&1) == 0:\n                    qc.x(i+d)\n            if n == d + 1:\n                qc.z(d)\n            else:\n                qc.append(ZGate().control(n-d-1), range(d, n))\n            for i in range(n-d):\n                if ((flip>>i)&1) == 0:\n                    qc.x(i+d)\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABC93FACE9319", "submission_order": 1, "result": "AC", "execution_time": "2362 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((1 << i) & l):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not((1 << i) & l):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABDED85715047", "submission_order": 1, "result": "WA", "execution_time": "1201 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    k = int.bit_length(L)\n    if L & (1 << (k-1)) == 0:\n        qc.x(k-1)\n    else:\n        qc.x(k-1)\n        qc.z(k-1)\n        qc.x(k-1)\n\n    for ii in range(k-1, 0, -1):\n        i = ii - 1\n        print(i)\n        if L & (1 << i) == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            for j in range(i+1, k):\n                qc.cz(i, j)\n            qc.x(i)\n\n    for i in range(k):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABDED85715047", "submission_order": 2, "result": "WA", "execution_time": "863 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    k = int.bit_length(L)\n    if L & (1 << (k-1)) == 0:\n        qc.x(k-1)\n    else:\n        qc.x(k-1)\n        qc.z(k-1)\n        qc.x(k-1)\n\n    for ii in range(k-1, 0, -1):\n        i = ii - 1\n        if L & (1 << i) == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            for j in range(i+1, k):\n                qc.cz(i, j)\n            qc.x(i)\n\n    for i in range(k):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABDED85715047", "submission_order": 3, "result": "WA", "execution_time": "974 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    k = int.bit_length(L)\n    if L & (1 << (k-1)) == 0:\n        qc.x(k-1)\n    else:\n        qc.x(k-1)\n        qc.z(k-1)\n        qc.x(k-1)\n\n    for ii in range(k-1, 0, -1):\n        i = ii - 1\n        print(i)\n        if L & (1 << i) == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i+1, k)), i)\n            qc.h(i)\n            qc.x(i)\n\n    for i in range(k):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABDED85715047", "submission_order": 4, "result": "WA", "execution_time": "923 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    k = int.bit_length(L)\n    if L & (1 << (k-1)) == 0:\n        qc.x(k-1)\n    else:\n        qc.x(k-1)\n        qc.z(k-1)\n        qc.x(k-1)\n\n    for ii in range(k-1, 0, -1):\n        i = ii - 1\n        if L & (1 << i) == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i+1, k)), i)\n            qc.h(i)\n            qc.x(i)\n\n    for i in range(k):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABDED85715047", "submission_order": 5, "result": "WA", "execution_time": "925 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    k = int.bit_length(L)\n\n    if L & (1 << (k-1)) == 0:\n        qc.x(k-1)\n    else:\n        qc.x(k-1)\n        qc.z(k-1)\n        qc.x(k-1)\n\n    for ii in range(k-1, 0, -1):\n        i = ii - 1\n        if L & (1 << i) == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i+1, k)), i)\n            qc.h(i)\n            qc.x(i)\n\n    for i in range(k):\n        if L & (1 << k) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABDED85715047", "submission_order": 6, "result": "AC", "execution_time": "1944 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if L & (1 << (n - 1)):\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n\n    for i in range(n - 2, -1, -1):\n        if L & (1 << (i)) == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i+1,n)), i)\n            qc.h(i)\n            qc.x(i)\n\n    for i in range(n):\n        if L & (1 << i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABE74EA2F4CC0", "submission_order": 1, "result": "WA", "execution_time": "921 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n-1):\n        qc.y(i)\n        qc.y(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABE74EA2F4CC0", "submission_order": 2, "result": "WA", "execution_time": "1053 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n-1):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABE74EA2F4CC0", "submission_order": 3, "result": "RE", "execution_time": "927 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(L):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABE74EA2F4CC0", "submission_order": 4, "result": "RE", "execution_time": "814 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(L-1):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABE74EA2F4CC0", "submission_order": 5, "result": "WA", "execution_time": "1003 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n-1):\n        qc.cz(i,i+1)\n        qc.cz(i+1,i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABE74EA2F4CC0", "submission_order": 6, "result": "WA", "execution_time": "1056 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABE74EA2F4CC0", "submission_order": 7, "result": "WA", "execution_time": "956 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n-1):\n        qc.cz(i,i+1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 1, "result": "RE", "execution_time": "767 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    for i in range(n-1):\n        qc.cz(i,i+1)\n    \n    for j in range(2**n-diff):\n        qc.x([k for k in range(n) if k != j])\n        for i in range(n-1):\n            qc.cz(i,i+1)\n        qc.x([k for k in range(n) if k != j])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 2, "result": "RE", "execution_time": "981 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    diff = 2**n - L\n    qc.h([i for i in range(n)])\n\n    for i in range(n-1):\n        qc.cz(i,i+1)\n    \n    for j in range(2**n-diff):\n        qc.x([k for k in range(n) if k != j])\n        for i in range(n-1):\n            qc.cz(i,i+1)\n        qc.x([k for k in range(n) if k != j])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 3, "result": "WA", "execution_time": "1372 ms", "memory": "104 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    for n in range(1,5+1):\n        qc = QuantumCircuit(n)\n        for L in range(1,2**n):\n            qc.h([i for i in range(n)])\n            if n == L == 1:\n                qc.z(0)\n            else:\n                for i in range(n-1):\n                    qc.cz(i,i+1)\n\n                for j in range(L):\n                    qc.x([k for k in range(n) if k != j])\n                    for i in range(n-1):\n                        qc.cz(i,i+1)\n                    qc.x([k for k in range(n) if k != j])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 4, "result": "WA", "execution_time": "1011 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    if n == L == 1:\n        qc.z(0)\n    else:\n        for i in range(n-1):\n            qc.cz(i,i+1)\n\n        for j in range(L):\n            qc.x([k for k in range(n) if k != j])\n            for i in range(n-1):\n                qc.cz(i,i+1)\n            qc.x([k for k in range(n) if k != j])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 5, "result": "WA", "execution_time": "978 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    if n == L == 1:\n        qc.z(0)\n    else:\n        for i in range(n-1):\n            qc.cz(i,i+1)\n        for j in range(L-1):\n            qc.x([k-1 for k in range(n) if k != j])\n            for i in range(n-1):\n                qc.cz(i,i+1)\n            qc.x([k-1 for k in range(n) if k != j])\n            qc.barrier()\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 6, "result": "WA", "execution_time": "973 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    if n == L == 1:\n        qc.z(0)\n    else:\n        for i in range(n-1):\n            qc.cz(i,i+1)\n        for j in range(L-1):\n            qc.x([k-1 for k in range(n) if k != j])\n            for i in range(n-1):\n                qc.cz(i,i+1)\n            qc.x([k-1 for k in range(n) if k != j])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 7, "result": "WA", "execution_time": "871 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    if n == L == 1:\n        qc.z(0)\n    else:\n        qc.x([i for i in range(n)])\n        for i in range(n-1):\n            qc.cz(i,i+1)\n        qc.x([i for i in range(n)])\n        for j in range(L-1):\n            if j == n:\n                for i in range(n-1):\n                    qc.cz(i,i+1)\n            else:\n                qc.x([k-1 for k in range(n) if k != j])\n                for i in range(n-1):\n                    qc.cz(i,i+1)\n                qc.x([k-1 for k in range(n) if k != j])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 8, "result": "WA", "execution_time": "1006 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    if n == L == 1:\n        qc.z(0)\n    else:\n        qc.x([i for i in range(n)])\n        for i in range(n-1):\n            qc.cz(i,i+1)\n        qc.x([i for i in range(n)])\n\n        for j in range(L-1):\n            if j == n:\n                for i in range(n-1):\n                    qc.cz(i,i+1)\n            else:\n                qc.x([k for k in range(n) if k != j])\n                for i in range(n-1):\n                    qc.cz(i,i+1)\n                qc.x([k for k in range(n) if k != j])\n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 9, "result": "RE", "execution_time": "786 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    U = MCPhaseGate(lam=math.pi, num_ctrl_qubits=n-1)\n    if n == L == 1:\n        qc.z(0)\n    else:\n        qc.x([i for i in range(n)])\n        qc.append(U,[i for i in range(n)])\n        qc.x([i for i in range(n)])\n        for j in range(L):\n            if j == n:\n                qc.append(U,[i for i in range(n)])\n            else:\n                qc.x([k for k in range(n) if k != j])\n                qc.append(U,[i for i in range(n)])\n                qc.x([k for k in range(n) if k != j])\n\n        \n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 10, "result": "RE", "execution_time": "811 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    U = MCPhaseGate(lam=math.pi, num_ctrl_qubits=n)\n    if n == L == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n    else:\n        qc.x([i for i in range(n)])\n        qc.append(U,[i for i in range(n)])\n        qc.x([i for i in range(n)])\n        for j in range(L):\n            if j == n:\n                qc.append(U,[i for i in range(n)])\n            else:\n                qc.x([k for k in range(n) if k != j])\n                qc.append(U,[i for i in range(n)])\n                qc.x([k for k in range(n) if k != j])\n\n        \n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 11, "result": "RE", "execution_time": "862 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    if n == L == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n\n    else:\n        U = MCPhaseGate(lam=math.pi, num_ctrl_qubits=n-1)\n        qc.x([i for i in range(n)])\n        qc.append(U,[i for i in range(n)])\n        qc.x([i for i in range(n)])\n        for j in range(L):\n            if j == n:\n                qc.append(U,[i for i in range(n)])\n            else:\n                qc.x([k for k in range(n) if k != j])\n                qc.append(U,[i for i in range(n)])\n                qc.x([k for k in range(n) if k != j])\n\n        \n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ABFEA2EC347B9", "submission_order": 12, "result": "RE", "execution_time": "895 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i for i in range(n)])\n    if n == L == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n\n    else:\n        U = MCPhaseGate(lam=math.pi, num_ctrl_qubits=n-)\n        qc.x([i for i in range(n)])\n        qc.append(U,[i for i in range(n)])\n        qc.x([i for i in range(n)])\n        for j in range(L-1):\n            if j == n:\n                qc.append(U,[i for i in range(n)])\n            else:\n                qc.x([k for k in range(n) if k != j])\n                qc.append(U,[i for i in range(n)])\n                qc.x([k for k in range(n) if k != j])\n\n        \n        \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC4ADA0AE6A31", "submission_order": 1, "result": "WA", "execution_time": "1143 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.x(i)\n        else:\n            qc.append(qlib.ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC4ADA0AE6A31", "submission_order": 2, "result": "WA", "execution_time": "1727 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.x(0)\n        else:\n            qc.append(qlib.ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC4ADA0AE6A31", "submission_order": 3, "result": "AC", "execution_time": "2800 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC53A836AADEA", "submission_order": 1, "result": "RE", "execution_time": "1931 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if (1 << i) & L != 0:\n            qc.append(PhaseGate(math.pi).control(i), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 1, "result": "RE", "execution_time": "936 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n            \n            # mcz\n            qc.h(i)\n            qc.mcx([j for j in ragne(i)], [i])\n            qc.h(i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 2, "result": "RE", "execution_time": "745 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n            \n            # mcz\n            qc.h(i)\n            qc.mcx([j for j in ragne(i)], [i]) if i > 0 else qc.x(0)\n            qc.h(i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 3, "result": "WA", "execution_time": "938 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n            \n            \n\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 4, "result": "RE", "execution_time": "889 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n            \n            # mcz\n            qc.h(i)\n            qc.mcx([j for j in ragne(i)], i)\n            qc.h(i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 5, "result": "RE", "execution_time": "820 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n            \n            # mcz\n            qc.h(i)\n            qc.mcx([j for j in ragne(i)], i) if i > 0 else qc.x(i)\n            qc.h(i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 1:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 6, "result": "RE", "execution_time": "947 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(i0)\n            \n            # mcz\n            qc.h(i)\n            qc.mcx([j for j in ragne(i)], i) if i > 0 else qc.x(i)\n            qc.h(i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 7, "result": "RE", "execution_time": "1026 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n-1, -1, -1):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(i0)\n            \n            # mcz\n            qc.h(i)\n            qc.mcx([j for j in ragne(i)], i) if i > 0 else qc.x(i)\n            qc.h(i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 8, "result": "RE", "execution_time": "898 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(i0)\n            \n            qc.mcp([j for j in ragne(i)], i) if i > 0 else qc.x(i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 9, "result": "RE", "execution_time": "787 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(i0)\n            \n            qc.mcp(pi, [j for j in ragne(i)], i) if i > 0 else qc.z(i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 10, "result": "RE", "execution_time": "955 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(n-1 - i0)\n            \n            qc.mcp(pi, [n-1 - j for j in ragne(i)], n-1 - i) if i > 0 else qc.z(n-1 - i)\n\n            for i0, v0 in enumerate(info):\n                if v0 == 0:\n                    qc.x(n-1 - i0)\n\n        info.append(v)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 11, "result": "RE", "execution_time": "832 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(pi, [n-1 - j for j in ragne(i)], n-1 - i) if i > 0 else qc.z(n-1 - i)\n\n            qc.x(n-1 - i0)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 12, "result": "RE", "execution_time": "983 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(pi, [n-1 - j for j in ragne(i)], n-1 - i) if i > 0 else qc.z(n-1 - i)\n\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 13, "result": "WA", "execution_time": "839 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.z(n-1 - i)\n\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 14, "result": "RE", "execution_time": "809 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(pi, n-1:n-1-i:-1, n-1 - i) if i > 0 else qc.z(n-1 - i)\n\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 15, "result": "RE", "execution_time": "835 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(pi, qc.qregs[0][n-1-i+1:n], n-1 - i) if i > 0 else qc.z(n-1 - i)\n\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 16, "result": "RE", "execution_time": "968 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    from math import pi\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(pi, range(n-1-i+1, n-1), n-1 - i) if i > 0 else qc.z(n-1 - i)\n\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 17, "result": "RE", "execution_time": "834 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    import math\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(math.pi, range(n-1-i+1,n), n-1 - i) if i > 0 else qc.z(n-1 - i)\n\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 18, "result": "RE", "execution_time": "756 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    import math\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(math.pi, range(n-1-i+1,n), n-1 - i) if i > 0 else qc.z(n-1 - i)\n\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 19, "result": "RE", "execution_time": "851 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    import math\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(math.pi, range(n-1-i+1,n), n-1 - i) if i > 0 else qc.p(math.pi, n-1 - i)\n\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AC6FE71426D0C", "submission_order": 20, "result": "RE", "execution_time": "1044 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L -= 1\n    import math\n    info = []\n    for i in range(n):\n        v = (L >> (n-1 - i)) & 1\n        if v == 0:\n            \n            qc.mcp(math.pi, range(n-1-i+1,n), n-1 - i)\n            qc.x(n-1 - i)\n\n        info.append(v)\n    \n    for i0, v0 in enumerate(info):\n        if v0 == 0:\n            qc.x(n-1 - i0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ACB64A6F1011B", "submission_order": 1, "result": "WA", "execution_time": "1113 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n      for j in range(n):\n        if i >> j & 1 == 0:\n          qc.x(j)\n      qc.z(range(n))\n      for j in range(n):\n        if i >> j & 1 == 0:\n          qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ACCADB9E0F247", "submission_order": 1, "result": "RE", "execution_time": "1539 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for mask in range(L):\n        for i in range(n):\n            if(not (mask & (1<<i))):\n                qc.x(i)\n        qc.append(ZGate().control(n-1, range(n)))\n        for i in range(n):\n            if(not (mask & (1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ACCADB9E0F247", "submission_order": 2, "result": "RE", "execution_time": "1386 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for mask in range(L):\n        for i in range(n):\n            if(not (mask & (1<<i))):\n                qc.x(i)\n        qc.append(ZGate().control(n-1, range(n)))\n        for i in range(n):\n            if(not (mask & (1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ACCADB9E0F247", "submission_order": 3, "result": "RE", "execution_time": "1049 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for mask in range(L):\n        for i in range(n):\n            if(not (mask & (1<<i))):\n                qc.x(i)\n        qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if(not (mask & (1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ACCADB9E0F247", "submission_order": 4, "result": "AC", "execution_time": "2564 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for mask in range(L):\n        for i in range(n):\n            if(not (mask & (1<<i))):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if(not (mask & (1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ACD3BD9375EAE", "submission_order": 1, "result": "RE", "execution_time": "1821 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        qc.x(i)\n    control_qubits = qr[0:n-1]  # First n-1 qubits are controls\n    target_qubit = qr[n-1]    # Last qubit is the target\n    mcz_gate = ZGate().control(num_ctrl_qubits=n - 1)\n    qc.append(mcz_gate, control_qubits[:] + [target_qubit])\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(1,L):\n        x = bin(i)[2:].zfill(n)\n        c=0\n        for j in range(n):\n            if x[j] == 1:\n                qc.z(c)\n                break\n            c+=1\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ACF367A74A9D6", "submission_order": 1, "result": "RE", "execution_time": "1677 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        for j in range(n):\n            if ~i >> j & 1: qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if ~i >> j & 1: qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ACF367A74A9D6", "submission_order": 2, "result": "AC", "execution_time": "2758 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        for j in range(n):\n            if ~i >> j & 1: qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if ~i >> j & 1: qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD0626EB3A97B", "submission_order": 1, "result": "RE", "execution_time": "1777 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\n#from qiskit import QuantumCircuit, QuantumRegister\n#from qiskit import transpile\n#from qiskit.circuit.library import RealAmplitudes\n#from qiskit.quantum_info import SparsePauliOp\n#from qiskit_aer import AerSimulator\n#from qiskit import QuantumCircuit\n#from qiskit.visualization import plot_histogram, plot_state_city\n\n\n\ndef flip(qc: QuantumCircuit, n: int, bit: int):\n    qc.append(ZGate().control(n - 1), range(n)) ## 0 に - 1 を掛ける\n    ## x^{i-1} 1 0^{n-i-1}\n    for i in range(bit):\n        qc.x(i)\n        if i == n - 1:\n            qc.z(n - 1)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n\n## [0, L) を flip\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    decompose = []\n    for i in range(n):\n        if (L >> i) & 1:\n            decompose = [(L - (1 << i), i)] + decompose\n    for (L, i) in decompose:\n        ## [L - (1 << i), L) を flip\n        flip(qc, n, i)\n        qc.x(i)\n    for (L, i) in decompose:\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n\n    #print(qc.depth())\n\n    #qc.save_statevector()\n    #simulator = AerSimulator(method='statevector')\n    #circ = transpile(qc, simulator)\n    #result = simulator.run(circ).result()\n    #statevector = result.get_statevector(circ)\n    #plot_state_city(statevector, title='Bell state', filename='statevector.png')\n    #print(statevector)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD19C314190B4", "submission_order": 1, "result": "RE", "execution_time": "2176 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for maska in range(L):\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n        qc.append(ZGate().control(n-1),range(n))\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD19C314190B4", "submission_order": 2, "result": "RE", "execution_time": "1008 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for maska in range(L):\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n        qc.append(ZGate().control(n),range(n))\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD19C314190B4", "submission_order": 3, "result": "RE", "execution_time": "1586 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for maska in range(L):\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n        qc.append(ZGate().control(n-1),range(n))\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD19C314190B4", "submission_order": 4, "result": "AC", "execution_time": "1779 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for maska in range(L):\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n        if (n == 1):\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1A6CEA6D870", "submission_order": 1, "result": "RE", "execution_time": "893 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n-1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1A6CEA6D870", "submission_order": 2, "result": "RE", "execution_time": "799 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(0), range(1))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1A6CEA6D870", "submission_order": 3, "result": "RE", "execution_time": "942 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(0), range())\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1A6CEA6D870", "submission_order": 4, "result": "WA", "execution_time": "1101 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # qc.append(ZGate().control(0), range())\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1A6CEA6D870", "submission_order": 5, "result": "WA", "execution_time": "896 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = ZGate()\n    # qc.append(ZGate().control(0), range())\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1A6CEA6D870", "submission_order": 6, "result": "RE", "execution_time": "824 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(0), range(1))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1A6CEA6D870", "submission_order": 7, "result": "RE", "execution_time": "823 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(CZGate().control(0), range(1))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1A6CEA6D870", "submission_order": 8, "result": "WA", "execution_time": "912 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = CZGate()\n    # qc.append(CZGate().control(0), range(1))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD1FFA50CBBFB", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "97 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD3A435BA7224", "submission_order": 1, "result": "AC", "execution_time": "1722 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD43D14169CDF", "submission_order": 1, "result": "RE", "execution_time": "2219 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((1 << i) & L == 0):\n                qc.x(i)\n            qc.append(ZGate().control(n - 1), range(n))\n            if (1 << i) & L == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD43D14169CDF", "submission_order": 2, "result": "RE", "execution_time": "1767 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if (1 << i) & L == 0:\n                qc.x(i)\n            qc.append(ZGate().control(n - 1), range(n))\n            if not((1 << i) & L == 0):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD43D14169CDF", "submission_order": 3, "result": "RE", "execution_time": "1781 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if (1 << i) & L == 0:\n                qc.x(i)\n        qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not((1 << i) & L == 0):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD43D14169CDF", "submission_order": 4, "result": "RE", "execution_time": "1567 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((1 << i) & L == 0):\n                qc.x(i)\n        qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not((1 << i) & L == 0):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD43D14169CDF", "submission_order": 5, "result": "RE", "execution_time": "1651 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((1 << i) & L):\n                qc.x(i)\n        qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not((1 << i) & L):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD43D14169CDF", "submission_order": 6, "result": "RE", "execution_time": "1313 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n        qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD43D14169CDF", "submission_order": 7, "result": "RE", "execution_time": "1483 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n        if z == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD43D14169CDF", "submission_order": 8, "result": "AC", "execution_time": "2090 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD4BD06344BA1", "submission_order": 1, "result": "RE", "execution_time": "1425 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n\n\n        for i in range(n):\n            if not(l>>i & 1):\n                qc.x(i)\n\n        qc.append(ZGate.control(n-1), range(n))\n        ## control(n-1): controlled by n-1 qbits.\n        ## range(n), this time, use 0~n-2 as controller, n-1 as target\n\n        for i in range(n):\n            if not(l>>i & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD4BD06344BA1", "submission_order": 2, "result": "RE", "execution_time": "1141 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n\n        for i in range(n):\n            if not(l>>i & 1):\n                qc.x(i)\n\n        if n>1:\n            qc.append(ZGate.control(n-1), range(n))\n        ## control(n-1): controlled by n-1 qbits.\n        ## range(n), this time, use 0~n-2 as controller, n-1 as target\n        else:\n            qc.z(0)\n\n        for i in range(n):\n            if not(l>>i & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD4BD06344BA1", "submission_order": 3, "result": "AC", "execution_time": "2440 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n\n        for i in range(n):\n            if not(l>>i & 1):\n                qc.x(i)\n\n        if n>1:\n            qc.append(ZGate().control(n-1), range(n))\n        ## control(n-1): controlled by n-1 qbits.\n        ## range(n), this time, use 0~n-2 as controller, n-1 as target\n        else:\n            qc.z(0)\n\n        for i in range(n):\n            if not(l>>i & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD55834DABEDF", "submission_order": 1, "result": "RE", "execution_time": "859 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.z(i)  # Zゲートを使用して複素振幅に -1 をかける\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD55834DABEDF", "submission_order": 2, "result": "RE", "execution_time": "1048 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD839C18884A5", "submission_order": 1, "result": "RE", "execution_time": "1240 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    qc = QuantumCircuit(x)\n\n    for i in range(L):\n        binary_i = format(i, f'0{n}b')\n        for j, bit in enumerate(binary_i):\n            if bit == '0':\n                qc.x(x[j])\n\n        qc.h(x[n-1])\n        qc.mcx(list(range(n-1)), x[n-1])\n        qc.h(x[n-1])\n\n        for j, bit in enumerate(binary_i):\n            if bit == '0':\n                qc.x(x[j])\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD839C18884A5", "submission_order": 2, "result": "RE", "execution_time": "1163 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    qc = QuantumCircuit(x)\n\n    for i in range(L):\n        binary_i = format(i, f'0{n}b')[::-1]\n        for j, bit in enumerate(binary_i):\n            if bit == '0':\n                qc.x(x[j])\n\n        qc.h(x[n-1])\n        qc.mcx(list(range(n-1)), x[n-1])\n        qc.h(x[n-1])\n\n        for j, bit in enumerate(binary_i):\n            if bit == '0':\n                qc.x(x[j])\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD839C18884A5", "submission_order": 3, "result": "RE", "execution_time": "1170 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    qc = QuantumCircuit(x)\n\n    for i in range(L):\n        binary_i = format(i, f'0{n}b')[::-1]\n        for j, bit in enumerate(binary_i):\n            if bit == '0':\n                qc.x(x[j])\n\n        if n == 1:\n            qc.z(x[0])\n        else:\n            qc.h(x[n-1])\n            qc.mcx(list(range(n-1)), x[n-1])\n            qc.h(x[n-1])\n\n        for j, bit in enumerate(binary_i):\n            if bit == '0':\n                qc.x(x[j])\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD839C18884A5", "submission_order": 4, "result": "RE", "execution_time": "1199 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    qc = QuantumCircuit(x)\n\n    for i in range(L):\n        for j in range(n):\n            if not (i >> j) & 1:\n                qc.x(x[j])\n\n        if n == 1:\n            qc.z(x[0])\n        else:\n            qc.h(x[n-1])\n            qc.mcx(list(range(n-1)), x[n-1])\n            qc.h(x[n-1])\n\n        for j in range(n):\n            if not (i >> j) & 1:\n                qc.x(x[j])\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD839C18884A5", "submission_order": 5, "result": "AC", "execution_time": "1714 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        for j in range(n):\n            if not (i >> j) & 1:\n                qc.x(j)\n\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.h(n-1)\n            qc.mcx(list(range(n-1)), n-1)\n            qc.h(n-1)\n\n        for j in range(n):\n            if not (i >> j) & 1:\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD856C099683A", "submission_order": 1, "result": "RE", "execution_time": "1800 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    for i in range(L):\n        s = \"\"\n        for k in range(1, n):\n            c = '1' if (i >> k & 1) else '0'\n            s += c\n        print(s)\n        if i % 2 == 0:\n            qc.append(XGate().control(n - 1, ctrl_state=s), range(n))\n        qc.append(ZGate().control(n - 1, ctrl_state=s), range(n))\n        if i % 2 == 0:\n            qc.append(XGate().control(n - 1, ctrl_state=s), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD856C099683A", "submission_order": 2, "result": "RE", "execution_time": "1452 ms", "memory": "157 MiB", "code": "'''python\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    for i in range(L):\n        s = \"\"\n        for k in range(1, n):\n            c = '1' if (i >> k & 1) else '0'\n            s += c\n        print(s)\n        append_gate = lambda gate: qc.append(gate(), [0]) if n == 1 else qc.append(gate().control(n - 1, ctrl_state = s), range(n))\n        if i % 2 == 0:\n            append_gate(XGate)\n        append_gate(ZGate)\n        if i % 2 == 0:\n            append_gate(XGate)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD856C099683A", "submission_order": 3, "result": "WA", "execution_time": "1600 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    for i in range(L):\n        s = \"\"\n        for k in range(1, n):\n            c = '1' if (i >> k & 1) else '0'\n            s += c\n        print(s)\n        append_gate = lambda gate: qc.append(gate(), [0]) if n == 1 else qc.append(gate().control(n - 1, ctrl_state = s), range(n))\n        if i % 2 == 0:\n            append_gate(XGate)\n        append_gate(ZGate)\n        if i % 2 == 0:\n            append_gate(XGate)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD856C099683A", "submission_order": 4, "result": "WA", "execution_time": "1383 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        s = \"\"\n        for k in range(1, n):\n            c = '1' if (i >> k & 1) else '0'\n            s += c\n        print(s)\n        append_gate = lambda gate: qc.append(gate(), [0]) if n == 1 else qc.append(gate().control(n - 1, ctrl_state = s), range(n))\n        if i % 2 == 0:\n            append_gate(XGate)\n        append_gate(ZGate)\n        if i % 2 == 0:\n            append_gate(XGate)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AD856C099683A", "submission_order": 5, "result": "AC", "execution_time": "2625 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        append_gate = lambda gate: qc.append(gate(), [0]) if n == 1 else \\\n                qc.append(gate().control(n - 1, ctrl_state = i & ((1 << n - 1) - 1)), range(n))\n        if not (i >> n - 1 & 1):\n            append_gate(XGate)\n        append_gate(ZGate)\n        if not (i >> n - 1 & 1):\n            append_gate(XGate)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "ADF7F9BA635EA", "submission_order": 1, "result": "WA", "execution_time": "943 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # 位相を反転する必要がある状態をマーキング\n    # ここでは |00>, |01>, |10> に該当\n    for i in range(L - 1):\n        # リトルエンディアン表現に基づくビットパターンを生成\n        bit_pattern = format(i, f'0{n}b')\n\n        # 必要な CNOT ゲートを適用\n        for qubit_idx, bit in enumerate(bit_pattern):\n            if bit == '0':\n                qc.x(qubit_idx)\n\n        # マルチ制御 Z ゲートを適用（ここでは単一の Z ゲートで代替）\n        qc.append(ZGate().control(n - 1), range(n))\n\n        # CNOT ゲートを元に戻す\n        for qubit_idx, bit in enumerate(bit_pattern):\n            if bit == '0':\n                qc.x(qubit_idx)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE05D7B7D7290", "submission_order": 1, "result": "RE", "execution_time": "909 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE05D7B7D7290", "submission_order": 2, "result": "AC", "execution_time": "2020 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE2DFCA20A999", "submission_order": 1, "result": "RE", "execution_time": "1143 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    i = 0\n    for i in range(L):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 1, "result": "WA", "execution_time": "1393 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 2, "result": "RE", "execution_time": "1415 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qml.z(0)\n    qml.x(0)\n    qml.z(0)\n    qml.x(0)\n    qml.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 3, "result": "RE", "execution_time": "1145 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 4, "result": "RE", "execution_time": "1451 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(CZ.control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 5, "result": "RE", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(Z.control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 6, "result": "RE", "execution_time": "1042 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(Z.control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 7, "result": "RE", "execution_time": "1039 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(z.control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 8, "result": "RE", "execution_time": "1073 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 9, "result": "RE", "execution_time": "1300 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 10, "result": "WA", "execution_time": "1047 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    for i in range(n):\n        qc.x(i)\n    \n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 11, "result": "RE", "execution_time": "1507 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3C015C62B1A", "submission_order": 12, "result": "AC", "execution_time": "2872 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3F7E622B508", "submission_order": 1, "result": "RE", "execution_time": "880 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n        for i in range(n):\n        qc.h(i)\n\n    is_flip = [0] * (2**n)\n\n    for i in range(L, 2**n):\n        if is_flip[i]:\n            continue\n        bits = []\n        q = i\n        pos = 0\n        while q > 0:\n            if q % 2:\n                bits.append(pos)\n            pos += 1\n            q >>= 1\n        for j in range(i, 2**n):\n            if (i & j) == i:\n                is_flip[j] ^= 1\n\n        print(bits)\n\n        if len(bits) == 1:\n            qc.z(bits[0])\n        else:\n            qc.append(ZGate().control(len(bits) - 1), bits)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3F7E622B508", "submission_order": 2, "result": "RE", "execution_time": "781 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    is_flip = [0] * (2**n)\n\n    for i in range(L, 2**n):\n        if is_flip[i]:\n            continue\n        bits = []\n        q = i\n        pos = 0\n        while q > 0:\n            if q % 2:\n                bits.append(pos)\n            pos += 1\n            q >>= 1\n        for j in range(i, 2**n):\n            if (i & j) == i:\n                is_flip[j] ^= 1\n\n        if len(bits) == 1:\n            qc.z(bits[0])\n        else:\n            qc.append(ZGate().control(len(bits) - 1), bits)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3F7E622B508", "submission_order": 3, "result": "RE", "execution_time": "951 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.h(i)\n\n    is_flip = [0] * (2**n)\n\n    for i in range(L, 2**n):\n        if is_flip[i]:\n            continue\n        bits = []\n        q = i\n        pos = 0\n        while q > 0:\n            if q % 2:\n                bits.append(pos)\n            pos += 1\n            q >>= 1\n        for j in range(i, 2**n):\n            if (i & j) == i:\n                is_flip[j] ^= 1\n\n        if len(bits) == 1:\n            qc.z(bits[0])\n        else:\n            qc.append(ZGate().control(len(bits) - 1), bits)\n\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3F7E622B508", "submission_order": 4, "result": "WA", "execution_time": "1007 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.h(i)\n\n    is_flip = [0] * (2**n)\n\n    for i in range(L, 2**n):\n        if is_flip[i]:\n            continue\n        bits = []\n        q = i\n        pos = 0\n        while q > 0:\n            if q % 2:\n                bits.append(pos)\n            pos += 1\n            q >>= 1\n        for j in range(i, 2**n):\n            if (i & j) == i:\n                is_flip[j] ^= 1\n\n        if len(bits) == 1:\n            qc.z(bits[0])\n        else:\n            qc.append(ZGate().control(len(bits) - 1), bits)\n\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE3F7E622B508", "submission_order": 5, "result": "AC", "execution_time": "1961 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    is_flip = [0] * (2**n)\n\n    for i in range(L, 2**n):\n        if is_flip[i]:\n            continue\n        bits = []\n        q = i\n        pos = 0\n        while q > 0:\n            if q % 2:\n                bits.append(pos)\n            pos += 1\n            q >>= 1\n        for j in range(i, 2**n):\n            if (i & j) == i:\n                is_flip[j] ^= 1\n\n        if len(bits) == 1:\n            qc.z(bits[0])\n        else:\n            qc.append(ZGate().control(len(bits) - 1), bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE4098D86B930", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n    \n    qc.append(GlobalPhase(theta=math.pi).control(n), range(n))\n\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE4098D86B930", "submission_order": 2, "result": "RE", "execution_time": "977 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n    \n    qc.append(GlobalPhase(phase=math.pi).control(n), range(n))\n\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE4098D86B930", "submission_order": 3, "result": "RE", "execution_time": "912 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n    \n    qc.append(GlobalPhaseGate(phas=math.pi).control(n), range(n))\n\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE4098D86B930", "submission_order": 4, "result": "RE", "execution_time": "888 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n    \n    qc.append(GlobalPhaseGat(phase=math.pi).control(n), range(n))\n\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE4098D86B930", "submission_order": 5, "result": "WA", "execution_time": "851 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n    \n    qc.append(GlobalPhaseGate(phase=math.pi).control(n), range(n))\n\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE4098D86B930", "submission_order": 6, "result": "WA", "execution_time": "1070 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<(n-1-j)))==0:\n                qc.x(j)\n    \n    qc.append(GlobalPhaseGate(phase=math.pi).control(n), range(n))\n\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<(n-1-j)))==0:\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE4098D86B930", "submission_order": 7, "result": "WA", "execution_time": "1224 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<(n-1-j)))==0:\n                qc.x(j)\n    \n        qc.append(GlobalPhaseGate(phase=math.pi).control(n), range(n))\n\n        for j in range(n):\n            if (i&(1<<(n-1-j)))==0:\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE4098D86B930", "submission_order": 8, "result": "AC", "execution_time": "2532 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n    \n        qc.append(GlobalPhaseGate(phase=math.pi).control(n), range(n))\n\n        for j in range(n):\n            if (i&(1<<j))==0:\n                qc.x(j)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 1, "result": "RE", "execution_time": "813 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(z.control(n-1),range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 2, "result": "RE", "execution_time": "829 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cz(i,n)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 3, "result": "RE", "execution_time": "883 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cz(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 4, "result": "WA", "execution_time": "945 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i<n-1:\n            qc.cz(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 5, "result": "WA", "execution_time": "1079 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i<n-1:\n            qc.cz(i+1,i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 6, "result": "RE", "execution_time": "849 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cz(i,n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 7, "result": "WA", "execution_time": "847 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1:\n        qc.z(0)\n    return qc\n    for i in range(n):\n        qc.cz(i,n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 8, "result": "RE", "execution_time": "857 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        h.(i)\n    if n==1:\n        qc.z(0)\n    return qc\n    for i in range(n):\n        qc.cz(i,n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 9, "result": "WA", "execution_time": "949 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    if n==1:\n        qc.z(0)\n    return qc\n    for i in range(n):\n        qc.cz(i,n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 10, "result": "RE", "execution_time": "810 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.append(x.control(n-1),range(n))\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 11, "result": "RE", "execution_time": "800 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mct(list(n-1),n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 12, "result": "RE", "execution_time": "797 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mct(list(range(n-1)),n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 13, "result": "RE", "execution_time": "953 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(z.control(n-1),n)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 14, "result": "RE", "execution_time": "848 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(z.control(n-1),range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 15, "result": "RE", "execution_time": "1024 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(x.control(n-1),range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 16, "result": "RE", "execution_time": "823 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(cz.control(n-1),range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 17, "result": "RE", "execution_time": "772 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(z().control(n-1),range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 18, "result": "RE", "execution_time": "893 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1:\n        return qc.z(0)\n    qc.h(range(n))\n    qc.append(z.control(n-1),range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 19, "result": "RE", "execution_time": "864 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.h(n-1)\n    qc.append(z.control(n-1),range(n))\n    qc.h(n-1)\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 20, "result": "RE", "execution_time": "966 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.h(n-1)\n    qc.append(x.control(n-1),range(n))\n    qc.h(n-1)\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 21, "result": "RE", "execution_time": "901 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.h(n-1)\n    qc.append(.control(n-2),range(n-1))\n    qc.h(n-1)\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 22, "result": "RE", "execution_time": "878 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.h(n-1)\n    qc.append(.control(L-1),range(n))\n    qc.h(n-1)\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE50189C09249", "submission_order": 23, "result": "RE", "execution_time": "800 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.h(n-1)\n    qc.append(z.control(L-1),range(n))\n    qc.h(n-1)\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 1, "result": "RE", "execution_time": "2034 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n\n    for i in range(L - 1):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.append(Gate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n\n    qc.append(Gate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n\n    for i in range(L - 1):\n        qc.append(Gate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 5, "result": "RE", "execution_time": "1952 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        for j in range(n):\n            if ((i >> j) & 0):\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 6, "result": "WA", "execution_time": "1887 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        for j in range(n):\n            if ((i >> j) & 1):\n                qc.z(j)\n            else:\n                qc.x(j)\n                qc.z(j)\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 7, "result": "RE", "execution_time": "1833 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(i)\n        qc.append(ZGate().control(n - 1), range(n))\n        for k in range(n):\n            if not ((i >> k) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 8, "result": "RE", "execution_time": "1981 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for k in range(n):\n            if not ((i >> k) & 1):\n                qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE61B9E559771", "submission_order": 9, "result": "AC", "execution_time": "2233 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(L):\n        for j in range(n):\n            if not ((i >> j) & 1):\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for k in range(n):\n            if not ((i >> k) & 1):\n                qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE7841C298EF9", "submission_order": 1, "result": "RE", "execution_time": "1487 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bitstr = format(i, f'0{n}b')  # i を nビットの2進数に変換\n        ctrl_bits = []\n\n        # Xゲートで0制御を実現（後で戻す）\n        for j, bit in enumerate(bitstr):\n            if bit == '0':\n                qc.x(j)\n            ctrl_bits.append(j)\n\n        # 多制御Zゲート：Zゲートに制御n-1個をつけて適用\n        mcZ = ZGate().control(n - 1)\n        qc.append(mcZ, ctrl_bits)\n\n        # Xゲートを元に戻す\n        for j, bit in enumerate(bitstr):\n            if bit == '0':\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE7841C298EF9", "submission_order": 2, "result": "RE", "execution_time": "1422 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n        bitstr = format(i, f'0{n}b')  # i を nビットの2進数に変換\n        ctrl_bits = []\n\n        # Xゲートで0制御を実現（後で戻す）\n        for j, bit in enumerate(bitstr):\n            if bit == '0':\n                qc.x(j)\n            ctrl_bits.append(j)\n\n        # 多制御Zゲート：Zゲートに制御n-1個をつけて適用\n        mcZ = ZGate().control(n - 1)\n        qc.append(mcZ, ctrl_bits)\n\n        # Xゲートを元に戻す\n        for j, bit in enumerate(bitstr):\n            if bit == '0':\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE95281D53808", "submission_order": 1, "result": "WA", "execution_time": "1019 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    flip = list()\n    for i in reversed(range(n)):\n        flip.append( L // 2**(i) )\n        L = L % 2**(i)\n    if flip[0]:\n        qc.z(n-1)\n    for i in range(1,n):\n        if flip[i]:\n            qc.append(ZGate().control(i), list(range(n-i,n))+[n-1-i])\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE95281D53808", "submission_order": 2, "result": "RE", "execution_time": "795 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for LL in range(L):\n        flip = list()\n        for i in reversed(range(n)):\n            flip.append( LL // 2**(i) )\n            LL = LL % 2**(i)\n        \n\n        for i in range(n):\n            if not flip[i]:\n                qc.z(i)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n         for i in range(n):\n            if not flip[i]:\n                qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE95281D53808", "submission_order": 3, "result": "RE", "execution_time": "938 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for LL in range(L):\n        flip = list()\n        for i in reversed(range(n)):\n            flip.append( LL // 2**(i) )\n            LL = LL % 2**(i)\n        \n\n        for i in range(n):\n            if not flip[i]:\n                qc.z(i)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not flip[i]:\n                qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE95281D53808", "submission_order": 4, "result": "WA", "execution_time": "846 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n      if L == 1:\n        qc.z(0)\n      return qc\n\n    for LL in range(L):\n        flip = list()\n        for i in reversed(range(n)):\n            flip.append( LL // 2**(i) )\n            LL = LL % 2**(i)\n\n        for i in range(n):\n            if not flip[i]:\n                qc.z(i)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not flip[i]:\n                qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE95281D53808", "submission_order": 5, "result": "WA", "execution_time": "965 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n      if L == 1:\n        qc.z(0)\n      return qc\n\n    for LL in range(L):\n        flip = list()\n        for i in reversed(range(n)):\n            flip.append( LL // 2**(i) )\n            LL = LL % 2**(i)\n        print(flip)\n        for i in range(n):\n            if not flip[i]:\n                qc.z(n-i-1)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not flip[i]:\n                qc.z(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE95281D53808", "submission_order": 6, "result": "WA", "execution_time": "1169 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n      if L == 1:\n        qc.z(0)\n      return qc\n\n    for LL in range(L):\n        flip = list()\n        for i in reversed(range(n)):\n            flip.append( LL // 2**(i) )\n            LL = LL % 2**(i)\n        print(flip)\n        for i in range(n):\n            if not flip[i]:\n                qc.x(i)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not flip[i]:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE95281D53808", "submission_order": 7, "result": "WA", "execution_time": "1218 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      if L == 2:\n        qc.z(0)\n      return qc\n\n    for LL in range(L):\n        flip = list()\n        for i in reversed(range(n)):\n            flip.append( LL // 2**(i) )\n            LL = LL % 2**(i)\n        for i in range(n):\n            if not flip[i]:\n                qc.x(i)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not flip[i]:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AE95281D53808", "submission_order": 8, "result": "AC", "execution_time": "3000 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      if L == 2:\n        qc.z(0)\n      return qc\n\n    for LL in range(L):\n        flip = list()\n        for i in reversed(range(n)):\n            flip.append( LL // 2**(i) )\n            LL = LL % 2**(i)\n        for i in range(n):\n            if not flip[i]:\n                qc.x(n-1-i)\n\n        qc.append(ZGate().control(n - 1), range(n))\n\n        for i in range(n):\n            if not flip[i]:\n                qc.x(n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEB579F553BD5", "submission_order": 1, "result": "RE", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEB579F553BD5", "submission_order": 2, "result": "RE", "execution_time": "795 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            if (l>>i)&1:\n                qc.x(i)\n        qc.append(XGate().control(0), range(n))\n        for i in range(n):\n            if (l>>i)&1:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEB579F553BD5", "submission_order": 3, "result": "RE", "execution_time": "798 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            if not (l>>i)&1:\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(0), range(n))\n        for i in range(n):\n            if not (l>>i)&1:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEB579F553BD5", "submission_order": 4, "result": "RE", "execution_time": "826 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i)&1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(0), range(n))\n        for i in range(n):\n            if not ((l>>i)&1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEB579F553BD5", "submission_order": 5, "result": "AC", "execution_time": "2773 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i)&1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not ((l>>i)&1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEC6B7F9DE236", "submission_order": 1, "result": "RE", "execution_time": "777 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        return qc\n    tmp = 0\n    for i in reversed(range(n)):\n        if tmp+(1<<i) < L:\n            if i == n-1:\n                qc.z(i)\n            qc.mcz(range(i+1,n),i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEC6B7F9DE236", "submission_order": 2, "result": "RE", "execution_time": "764 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        return qc\n    tmp = 0\n    for i in reversed(range(n)):\n        if tmp+(1<<i) < L:\n            if i == n-1:\n                qc.z(i)\n            else:\n                qc.mcz(range(i+1,n),i)\n            tmp += (1<<i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEC6B7F9DE236", "submission_order": 3, "result": "WA", "execution_time": "968 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        return qc\n    tmp = 0\n    for i in reversed(range(n)):\n        if tmp+(1<<i) < L:\n            if i == n-1:\n                qc.z(i)\n            else:\n                qc.mcx(list(range(i+1,n)),i)\n            tmp += (1<<i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEC6B7F9DE236", "submission_order": 4, "result": "WA", "execution_time": "939 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    if L == (1<<n):\n        return qc\n    tmp = 0\n    tmp_flip = []\n    for i in reversed(range(n)):\n        print(tmp)\n        print(1<<i)\n        if tmp+(1<<i) <= L:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                for y in tmp_flip:\n                    qc.x(y)\n                qc.x(i)\n                qc.h(i)\n                qc.mcx(list(range(i+1,n)),i)\n                qc.h(i)\n                qc.x(i)\n                for y in tmp_flip:\n                    qc.x(y)\n            tmp += (1<<i)\n        else:\n            tmp_flip.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEC6B7F9DE236", "submission_order": 5, "result": "WA", "execution_time": "957 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    if L == (1<<n):\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n        qc.z(n-1)\n        return qc\n    tmp = 0\n    tmp_flip = []\n    for i in reversed(range(n)):\n        print(tmp)\n        print(1<<i)\n        if tmp+(1<<i) <= L:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                for y in tmp_flip:\n                    qc.x(y)\n                qc.x(i)\n                qc.h(i)\n                qc.mcx(list(range(i+1,n)),i)\n                qc.h(i)\n                qc.x(i)\n                for y in tmp_flip:\n                    qc.x(y)\n            tmp += (1<<i)\n        else:\n            tmp_flip.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEC6B7F9DE236", "submission_order": 6, "result": "WA", "execution_time": "994 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    if L == (1<<n):\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n        qc.z(n-1)\n        return qc\n    tmp = 0\n    tmp_flip = []\n    for i in reversed(range(n)):\n        # print(tmp)\n        # print(1<<i)\n        if tmp+(1<<i) <= L:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                for y in tmp_flip:\n                    qc.x(y)\n                qc.x(i)\n                qc.h(i)\n                qc.mcx(list(range(i+1,n)),i)\n                qc.h(i)\n                qc.x(i)\n                for y in tmp_flip:\n                    qc.x(y)\n            tmp += (1<<i)\n        else:\n            tmp_flip.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEC6B7F9DE236", "submission_order": 7, "result": "AC", "execution_time": "1579 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n        qc.z(n-1)\n        return qc\n    tmp = 0\n    tmp_flip = []\n    for i in reversed(range(n)):\n        # print(tmp)\n        # print(1<<i)\n        if tmp+(1<<i) <= L:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                for y in tmp_flip:\n                    qc.x(y)\n                qc.x(i)\n                qc.h(i)\n                qc.mcx(list(range(i+1,n)),i)\n                qc.h(i)\n                qc.x(i)\n                for y in tmp_flip:\n                    qc.x(y)\n            tmp += (1<<i)\n        else:\n            tmp_flip.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEFEC2517543D", "submission_order": 1, "result": "RE", "execution_time": "2532 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if l>>i & 1 == 0 :\n                qc.x(i)\n\n        qc.append(XGate().control(n-1), range(n))\n\n        for i in range(n):\n            if l>>i & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEFEC2517543D", "submission_order": 2, "result": "RE", "execution_time": "1908 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if l>>i & 1 == 0 :\n                qc.x(i)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            if l>>i & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEFEC2517543D", "submission_order": 3, "result": "RE", "execution_time": "1829 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if l>>i & 1 == 0 :\n                qc.x(i)\n\n        qc.append(ZGate().control(n-1), n)\n\n        for i in range(n):\n            if l>>i & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEFEC2517543D", "submission_order": 4, "result": "RE", "execution_time": "2103 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if l>>i & 1 == 0 :\n                qc.x(i)\n\n        qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            if l>>i & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AEFEC2517543D", "submission_order": 5, "result": "AC", "execution_time": "2175 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for l in range(L):\n        for i in range(n):\n            if l>>i & 1 == 0 :\n                qc.x(i)\n        \n        if n == 1:\n            qc.z(0)\n\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            if l>>i & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF1E827F11CD9", "submission_order": 1, "result": "WA", "execution_time": "1154 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    same = ''\n    for i in range(n-1, -1, -1):\n        nxt = L >> i & 1\n        if nxt == 1:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n-i-1, ctrl_state=same), range(n-1, i-1, -1))\n                qc.x(i)\n        same += str(nxt)\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_B3", "user": "AF1E827F11CD9", "submission_order": 2, "result": "AC", "execution_time": "1889 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    same = ''\n    for i in range(n-1, -1, -1):\n        nxt = L >> i & 1\n        if nxt == 1:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n-i-1, ctrl_state=same), range(n-1, i-1, -1))\n                qc.x(i)\n        same = str(nxt) + same\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_B3", "user": "AF2AEAD1F2B66", "submission_order": 1, "result": "AC", "execution_time": "2859 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not (l>>i & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not (l>>i & 1):\n                qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF3AC2BC82212", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not (l>>i & 1):\n                qc.x(i)\n        if (n==1):\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if not (l>>j & 1):\n                qc.x(j)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF3AC2BC82212", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if (n==1):\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if not ((l>>j) & 1):\n                qc.x(j)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF3AC2BC82212", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if not ((l>>j) & 1):\n                qc.x(j)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF3AC2BC82212", "submission_order": 4, "result": "AC", "execution_time": "2224 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if not ((l>>j) & 1):\n                qc.x(j)\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF79548708498", "submission_order": 1, "result": "RE", "execution_time": "1741 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef create_oracle(n, L):\n    # Create a quantum register with n qubits\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n\n    # Apply the oracle O\n    for i in range(L):\n        # Convert i to binary and apply the necessary gates\n        binary_representation = format(i, f'0{n}b')  # Get binary representation of i with n bits\n        control_bits = [int(bit) for bit in binary_representation]  # Convert to list of bits\n        \n        # Apply a controlled-Z gate (or equivalent) to flip the sign\n        # We can use a series of CNOTs to achieve this\n        for j in range(n):\n            if control_bits[j] == 1:\n                # Apply a CNOT from control qubit to the last qubit (target)\n                if j == n - 1:\n                    # If the control is the last qubit, we need to apply a Z gate instead\n                    qc.z(qr[j])\n                else:\n                    qc.cx(qr[j], qr[n - 1])  # CNOT from control to target\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF79548708498", "submission_order": 2, "result": "RE", "execution_time": "2075 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply a multi-controlled Z gate for states 0 to L-1\n    # We will use a series of CNOT gates to create the effect of a multi-controlled Z gate\n    for i in range(L):\n        # Convert i to binary and apply CNOTs\n        binary_representation = format(i, f'0{n}b')  # Get binary representation of i with n bits\n        for j in range(n):\n            if binary_representation[j] == '1':\n                qc.x(j)  # Apply X gate to flip the qubit to |1> if needed\n        qc.h(n-1)  # Apply Hadamard to the last qubit to create superposition\n        qc.mct(list(range(n-1)), n-1)  # Apply multi-controlled Toffoli (mct) to flip the last qubit\n        qc.h(n-1)  # Apply Hadamard to the last qubit to revert it back\n        for j in range(n):\n            if binary_representation[j] == '1':\n                qc.x(j)  # Revert the X gates to restore original state\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 1, "result": "RE", "execution_time": "888 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def flip_phase(i):\n        bits = [b == \"1\" for b in f\"{i:05b}\"][::-1]\n        for j in range(n):\n            if bits[j]:\n                qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            if bits[j]:\n                qc.x(j)\n    for i in range(L):\n        flip_phase(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 2, "result": "RE", "execution_time": "1093 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def flip_phase(i):\n        bits = [b == \"1\" for b in f\"{i-1:05b}\"][::-1]\n        for j in range(n):\n            if bits[j]:\n                qc.x(j)\n            qc.append(ZGate().control(n - 1), range(n))\n            if bits[j]:\n                qc.x(j)\n    for i in range(L):\n        flip_phase(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 3, "result": "RE", "execution_time": "1302 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    for i in range(L):\n        bits = [b == \"1\" for b in f\"{i:05b}\"[::-1]]\n        # print(i, bits)\n        for j in range(n):\n            if bits[j]:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 4, "result": "RE", "execution_time": "1273 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    for i in range(L):\n        bits = [b == \"1\" for b in f\"{i:05b}\"]\n        # print(i, bits)\n        for j in range(n):\n            if bits[j]:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 5, "result": "RE", "execution_time": "1388 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    for i in range(L):\n        bits = [b == \"1\" for b in f\"{i:05b}\"[::-1]]\n        # print(i, bits)\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 6, "result": "RE", "execution_time": "1318 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n    for i in range(L):\n        bits = [b == \"1\" for b in f\"{i:05b}\"]\n        # print(i, bits)\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 7, "result": "RE", "execution_time": "1402 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bits = [b == \"1\" for b in f\"{i:05b}\"]\n        # print(i, bits)\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 8, "result": "RE", "execution_time": "1299 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bits = [b == \"1\" for b in f\"{i:05b}\"[::-1]]\n        # print(i, bits)\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 9, "result": "WA", "execution_time": "1364 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bits = [b == \"1\" for b in f\"{i:05b}\"]\n        # print(i, bits)\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF8CF426EF254", "submission_order": 10, "result": "AC", "execution_time": "2651 ms", "memory": "97 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        bits = [b == \"1\" for b in f\"{i:05b}\"[::-1]]\n        # print(i, bits)\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if not bits[j]:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AF948577476DF", "submission_order": 1, "result": "AC", "execution_time": "1913 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L %= 1 << n\n\n    def rec(n: int, L: int, control: list[int]):\n        if n == 0:\n            return\n        nonlocal qc\n        i = n - 1\n        w = 1 << i\n        def X():\n            nonlocal qc\n            if control:\n                qc.append(XGate().control(len(control)), list(control) + [i])\n            else:\n                qc.x(i)\n        def Z():\n            nonlocal qc\n            if control:\n                qc.append(ZGate().control(len(control)), list(control) + [i])\n            else:\n                qc.z(i)\n        X()\n        rev = L >= w\n        if rev:\n            Z()\n            L -= w\n            X()\n        rec(i, L, control + [i])\n        if not rev:\n            X()\n    \n    rec(n, L, [])\n    \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFA0EA513BE1B", "submission_order": 1, "result": "RE", "execution_time": "1150 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    #for i in range(n):\n    #    qc.h(i)\n\n    for set in range(L):\n        #print(format(set, f'0{n-1}b'))\n\n        if not (set >> (n - 1)) & 1:\n            qc.x(n-1)\n            s = format(set, f'0{n-1}b')\n            qc.append(ZGate().control(n - 1, ctrl_state=s), range(n))\n            qc.x(n-1)\n        else:\n            s = format(set - (1 << (n - 1)), f'0{n-1}b')\n            qc.append(ZGate().control(n - 1, ctrl_state=s), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFA0EA513BE1B", "submission_order": 2, "result": "AC", "execution_time": "1879 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    #for i in range(n):\n    #    qc.h(i)\n\n    if n > 1:\n        for set in range(L):\n            #print(format(set, f'0{n-1}b'))\n\n            if not (set >> (n - 1)) & 1:\n                qc.x(n-1)\n                s = format(set, f'0{n-1}b')\n                qc.append(ZGate().control(n - 1, ctrl_state=s), range(n))\n                qc.x(n-1)\n            else:\n                s = format(set - (1 << (n - 1)), f'0{n-1}b')\n                qc.append(ZGate().control(n - 1, ctrl_state=s), range(n))\n    else:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFB17B29114F9", "submission_order": 1, "result": "RE", "execution_time": "860 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(L - 1), range(L))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFB17B29114F9", "submission_order": 2, "result": "RE", "execution_time": "864 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(z().control(L - 1), range(L))\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFB17B29114F9", "submission_order": 3, "result": "RE", "execution_time": "962 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.z(L)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFBB9BD27D3DD", "submission_order": 1, "result": "RE", "execution_time": "844 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n from qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFBB9BD27D3DD", "submission_order": 2, "result": "RE", "execution_time": "977 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFBB9BD27D3DD", "submission_order": 3, "result": "RE", "execution_time": "1053 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(L))\n \n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 1, "result": "RE", "execution_time": "1660 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bit = \"0\" + str(n) + \"b\"\n\n    for l in range(L):\n        binN = format(l, bit)\n        for k in range(n):\n            if binN[n-k-1] == '0':\n                qc.x(k)\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 2, "result": "RE", "execution_time": "1694 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bit = \"0\" + str(n) + \"b\"\n\n    for l in range(L):\n        binN = format(l, bit)\n        for k in range(n):\n            if binN[n-k-1] == '0':\n                qc.x(k)\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    for k in range(n):\n        if binN[n-k-1] == '0':\n            qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 3, "result": "RE", "execution_time": "1467 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bit = \"0\" + str(n) + \"b\"\n\n    for l in range(L-1):\n        binN = format(l, bit)\n        for k in range(n):\n            if binN[n-k-1] == '0':\n                qc.x(k)\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    for k in range(n):\n        if binN[n-k-1] == '0':\n            qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 4, "result": "RE", "execution_time": "1518 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bit = \"0\" + str(n) + \"b\"\n\n    for l in range(L-1):\n        binN = format(l, bit)\n        for k in range(n):\n            if binN[n-k-1] == '0':\n                qc.x(k)\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    for k in range(n):\n        if binN[n-k-1] == '0':\n            qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 5, "result": "RE", "execution_time": "1554 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bit = \"0\" + str(n) + \"b\"\n\n    for l in range(L):\n        binN = format(l, bit)\n        for k in range(n):\n            if binN[n-k-1] == '0':\n                qc.x(k)\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    for k in range(n):\n        if binN[n-k-1] == '0':\n            qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 6, "result": "RE", "execution_time": "1627 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bit = \"0\" + str(n) + \"b\"\n\n    for l in range(L):\n        binN = format(l, bit)\n        for k in range(n):\n            if binN[n-k-1] == '0':\n                qc.x(k)\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    for k in range(n):\n        if binN[n-k-1] == '0':\n            qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 7, "result": "RE", "execution_time": "1782 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bit = \"0\" + str(n) + \"b\"\n\n    for l in range(L):\n        binN = format(l, bit)\n        for k in range(n):\n            if binN[n-k-1] == '0':\n                qc.x(k)\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    for k in range(n):\n        if binN[n-k-1] == '0':\n            qc.x(k)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 8, "result": "RE", "execution_time": "1440 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nfor l in range(L):\n    for i in range(n):\n        #check if i-th bit of l is 0 or 1\n        if not((l >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.z(0)\n    else:\n        # apply multiple controlled z gate\n        qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 9, "result": "RE", "execution_time": "1441 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nfor l in range(L):\n    for i in range(n):\n        #check if i-th bit of l is 0 or 1\n        if not((l >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.z(0)\n    else:\n        # apply multiple controlled z gate\n        qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 10, "result": "RE", "execution_time": "1368 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nfor l in range(L):\n    for i in range(n):\n        #check if i-th bit of l is 0 or 1\n        if not((l >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.z(0)\n    else:\n        # apply multiple controlled z gate\n        qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 11, "result": "RE", "execution_time": "1339 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nfor l in range(L):\n    for i in range(n):\n        #check if i-th bit of l is 0 or 1\n        if not((l >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.z(0)\n    else:\n        # apply multiple controlled z gate\n        qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 12, "result": "RE", "execution_time": "1285 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nfor l in range(L):\n    for i in range(n):\n        #check if i-th bit of l is 0 or 1\n        if not((l >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.z(0)\n    else:\n        # apply multiple controlled z gate\n        qc.append(ZGate().control(n - 1), list(range(n)))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFC5344A7A3BD", "submission_order": 13, "result": "RE", "execution_time": "1287 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nfor l in range(L):\n    for i in range(n):\n        #check if i-th bit of l is 0 or 1\n        if not((l >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.z(0)\n    else:\n        # apply multiple controlled z gate\n        qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFD534DE7C675", "submission_order": 1, "result": "RE", "execution_time": "1053 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    qc.append(ZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFD534DE7C675", "submission_order": 2, "result": "RE", "execution_time": "1159 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(ZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFD534DE7C675", "submission_order": 3, "result": "RE", "execution_time": "1524 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for bits in range(L):\n        for i in range(n):\n            if (bits>>i)&1:\n                pass\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (bits>>i)&1:\n                pass\n            else:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFD534DE7C675", "submission_order": 4, "result": "AC", "execution_time": "3000 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        else:\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n    for bits in range(L):\n        for i in range(n):\n            if (bits>>i)&1:\n                pass\n            else:\n                qc.x(i)\n        qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (bits>>i)&1:\n                pass\n            else:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFD6426194F25", "submission_order": 1, "result": "RE", "execution_time": "1210 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for d in range(n):\n            if (1<<d) & l == 0:\n                qc.x(d)\n        qc.append(ZGate().control(n-1), range(n))\n        for d in range(n):\n            if (1<<d) & l == 0:\n                qc.x(d)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFD6426194F25", "submission_order": 2, "result": "WA", "execution_time": "1171 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for d in range(n):\n            if (1<<d) & l == 0:\n                qc.x(d)\n        if n > 1:\n            qc.append(ZGate().control(n-1), range(n))\n        for d in range(n):\n            if (1<<d) & l == 0:\n                qc.x(d)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFD6426194F25", "submission_order": 3, "result": "AC", "execution_time": "2181 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for d in range(n):\n            if (1<<d) & l == 0:\n                qc.x(d)\n        if n > 1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n        for d in range(n):\n            if (1<<d) & l == 0:\n                qc.x(d)\n\n    return qc\n'''"}
{"problem": "QPC001_B3", "user": "AFE5EC74FECCE", "submission_order": 1, "result": "AC", "execution_time": "2930 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef find_one_positions(n):\n    positions = []\n    position = 0\n\n    while n:\n        if n & 1:\n            positions.append(position)\n        n >>= 1\n        position += 1\n\n    return positions\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # qc.h(0)\n    # qc.cnot(0, 1)\n    # qc.h(1)\n\n    neg_list = [0]*(2**n)\n    for i in range(L, 2**n):\n        print(neg_list)\n        pos1 = find_one_positions(i)\n        if neg_list[i] == 0: \n            if len(pos1) == 1:\n                qc.p(math.pi, pos1[0])\n            else:\n                qc.mcp(math.pi, pos1[1:], pos1[0])\n            for m in range(2**n):\n                pos1m = find_one_positions(m)\n                if all(elem in pos1m for elem in pos1):\n                    print(m)\n                    neg_list[m] = 1 - neg_list[m]\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A0151CF838AB2", "submission_order": 1, "result": "RE", "execution_time": "1012 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from qiskit.circuit.library import ZGate\n    for i in range(1,n+1):# 第i+1 qubitから第n qubit までbin(L)と一致するような量子ビットb<Lに対して操作を行う\n        for j in range(i,n):# bin(L)の第i+1桁からn桁目までのうち0であるものに対しxを作用させる（i+1桁以降が全部1になる）\n            if(not (L>>(j) & 1)):\n                qc.x(j)\n        qc.x(i-1) # i番目の0と1を入れ替えておく．これで1になるものに対し係数の符号を反転させる\n        if(i==n):\n            qc.x(n-1)\n        else:\n            v=[]\n            for k in range(i,n):\n                v.append(k)\n            v.append(i-1)\n            qc.append(ZGate.control(n-i),v)\n\n        qc.x(i-1)\n        for j in range(i,n):# bin(L)の第i+1桁からn桁目までのうち0であるものに対しxを作用させる（i+1桁以降が全部1になる）\n            if(not (L>>(j) & 1)):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A0151CF838AB2", "submission_order": 2, "result": "WA", "execution_time": "892 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from qiskit.circuit.library import ZGate\n    for i in range(1,n+1):# 第i+1 qubitから第n qubit までbin(L)と一致するような量子ビットb<Lに対して操作を行う\n        for j in range(i,n):# bin(L)の第i+1桁からn桁目までのうち0であるものに対しxを作用させる（i+1桁以降が全部1になる）\n            if(not (L>>j & 1)):\n                qc.x(j)\n        qc.x(i-1) # i番目の0と1を入れ替えておく．これで1になるものに対し係数の符号を反転させる\n        if(i==n):\n            qc.x(n-1)\n        else:\n            v=[]\n            for k in range(i,n):\n                v.append(k)\n            v.append(i-1)\n            qc.append(ZGate().control(n-i),v)\n\n        qc.x(i-1)\n        for j in range(i,n):# bin(L)の第i+1桁からn桁目までのうち0であるものに対しxを作用させる（i+1桁以降が全部1になる）\n            if(not (L>>(j) & 1)):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A0151CF838AB2", "submission_order": 3, "result": "WA", "execution_time": "887 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from qiskit.circuit.library import ZGate\n    for i in range(1,n+1):# 第i+1 qubitから第n qubit までbin(L)と一致するような量子ビットb<Lに対して操作を行う\n        for j in range(i,n):# bin(L)の第i+1桁からn桁目までのうち0であるものに対しxを作用させる（i+1桁以降が全部1になる）\n            if(not (L>>j & 1)):\n                qc.x(j)\n        qc.x(i-1) # i番目の0と1を入れ替えておく．これで1になるものに対し係数の符号を反転させる\n        if(i==n):\n            qc.z(n-1)\n        else:\n            v=[]\n            for k in range(i,n):\n                v.append(k)\n            v.append(i-1)\n            qc.append(ZGate().control(n-i),v)\n\n        qc.x(i-1)\n        for j in range(i,n):# bin(L)の第i+1桁からn桁目までのうち0であるものに対しxを作用させる（i+1桁以降が全部1になる）\n            if(not (L>>(j) & 1)):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A0151CF838AB2", "submission_order": 4, "result": "AC", "execution_time": "1751 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from qiskit.circuit.library import ZGate\n    for i in range(1,n+1):# 第i+1 qubitから第n qubit までbin(L)と一致するような量子ビットb<Lに対して操作を行う\n        if not ((L>>i-1)&1):\n            continue\n\n        for j in range(i,n):# bin(L)の第i+1桁からn桁目までのうち0であるものに対しxを作用させる（i+1桁以降が全部1になる）\n            if(not (L>>j & 1)):\n                qc.x(j)\n        qc.x(i-1) # i番目の0と1を入れ替えておく．これで1になるものに対し係数の符号を反転させる\n        if(i==n):\n            qc.z(n-1)\n        else:\n            qc.append(ZGate().control(n-i),range(i-1,n))\n        qc.x(i-1)\n        for j in range(i,n):# bin(L)の第i+1桁からn桁目までのうち0であるものに対しxを作用させる（i+1桁以降が全部1になる）\n            if(not (L>>j & 1)):\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A01E97158DA31", "submission_order": 1, "result": "DLE", "execution_time": "1481 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A01E97158DA31", "submission_order": 2, "result": "AC", "execution_time": "1623 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L:int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  \n  for i in range(n):\n    if not (L >> i) & 1:\n      continue\n    for j in range(i + 1, n):\n      if not (L >> j) & 1:\n        qc.x(j)\n    qc.x(i)\n    if i == n - 1:\n      qc.z(i)\n    else:\n      qc.append(ZGate().control(n - i - 1), range(i, n))\n    qc.x(i)\n    for j in range(i + 1, n):\n      if not (L >> j) & 1:\n        qc.x(j)\n      \n  return qc\n'''"}
{"problem": "QPC001_B4", "user": "A0318FE244CDA", "submission_order": 1, "result": "AC", "execution_time": "1564 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A0392EC280FDD", "submission_order": 1, "result": "AC", "execution_time": "2045 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & (1 << i) == 0:\n            continue\n        for j in range(i + 1,n):\n            if L & (1 << j) == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1,n):\n            if L & (1 << j) == 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A054E6D9B04ED", "submission_order": 1, "result": "AC", "execution_time": "2863 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A0AF5F5F2CE47", "submission_order": 1, "result": "AC", "execution_time": "1789 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# def intlog2_math(v):\n#     return int(math.floor(math.log2(v)))\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    M = n\n    if M == 0:\n        return qc\n    b = get_bit(L, M - 1)\n    if b == 0:\n        qc.x(M - 1)\n    else:\n        qc.x(M - 1)\n        qc.z(M - 1)\n        qc.x(M - 1)\n    \n    for i in list(range(M - 1))[::-1]:\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i + 1, M)), i)\n            qc.h(i)\n            qc.x(i)\n    \n    for i in range(M):\n        b = get_bit(L, i)\n        if b == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A0F7C763A034B", "submission_order": 1, "result": "AC", "execution_time": "2614 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    i = 0\n    while(L > 0) and i < n:\n        r = L % 2\n        L = L // 2\n        if(r == 1):\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.mcp(math.pi, [x for x in range(i+1, n)], i, ctrl_state=L)\n                qc.x(i)\n\n        i += 1\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A1333462B19D5", "submission_order": 1, "result": "AC", "execution_time": "1195 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if L & (1 << (n - 1)):\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n\n    for i in range(n - 2, -1, -1):\n        if L & (1 << (i)) == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.h(i)\n            qc.mcx(list(range(i+1,n)), i)\n            qc.h(i)\n            qc.x(i)\n\n    for i in range(n):\n        if L & (1 << i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A16408BC857A1", "submission_order": 1, "result": "RE", "execution_time": "1616 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    lbit = l.bit_length()\n    for i in range(lbit - 1):\n        for j in range(i + 1, n):\n            qc.x(j)\n        \n        qc.append(ZGate().control(n - 1), range(i, n))\n\n        for j in range(i + 1, n):\n            qc.x(j)\n\n    for i in range(2**lbit, l):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A16408BC857A1", "submission_order": 2, "result": "RE", "execution_time": "1578 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    lbit = L.bit_length()\n    for i in range(lbit - 1):\n        for j in range(i + 1, n):\n            qc.x(j)\n        \n        qc.append(ZGate().control(n - 1), range(i, n))\n\n        for j in range(i + 1, n):\n            qc.x(j)\n\n    for i in range(2**lbit, L):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A16408BC857A1", "submission_order": 3, "result": "RE", "execution_time": "1599 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    lbit = L.bit_length()\n    for i in range(lbit - 1):\n        for j in range(i + 1, n):\n            qc.x(j)\n        \n        qc.append(ZGate().control(n - 1), range(i, n))\n\n        for j in range(i + 1, n):\n            qc.x(j)\n\n    for i in range(2**(lbit - 1), L):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A16408BC857A1", "submission_order": 4, "result": "WA", "execution_time": "1814 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    lbit = L.bit_length()\n    for i in range(lbit - 1):\n        for j in range(i + 1, n):\n            qc.x(j)\n        \n        if i == n - 1:\n            qc.z(n - 1)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n\n        for j in range(i + 1, n):\n            qc.x(j)\n\n    for i in range(2**(lbit - 1), L):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A16408BC857A1", "submission_order": 5, "result": "RE", "execution_time": "1722 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.append(ZGate().control(n - 1), range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n    lbit = L.bit_length()\n    for i in range(lbit - 1):\n        for j in range(i + 1, n):\n            qc.x(j)\n        \n        if i == n - 1:\n            qc.z(n - 1)\n        else:\n            print(f'num: {n - i}, c: ({i}, {n})', flush=True)\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n\n        for j in range(i + 1, n):\n            qc.x(j)\n\n    for i in range(2**(lbit - 1), L):\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n\n        for j in range(n):\n            if (i >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A16408BC857A1", "submission_order": 6, "result": "WA", "execution_time": "1961 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n\n    for i in range(n):\n        if (L >> i) & 1 == 0:\n            continue\n        \n        qc.x(i)\n        for j in range(i + 1, n):\n            if (L >> j) & 1 == 0:\n                qc.x(j)\n        \n        if i == n - 1:\n            qc.z(n - 1)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n\n        qc.x(i)\n        for j in range(i + 1, n):\n            if (L >> j) & 1 == 0:\n                qc.x(j)\n    \n    \n    for j in range(n):\n        if (L >> j) & 1 == 0:\n            qc.x(j)\n    \n    qc.append(ZGate().control(n - 1), range(n))\n\n    for j in range(n):\n        if (L >> j) & 1 == 0:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A16408BC857A1", "submission_order": 7, "result": "WA", "execution_time": "1929 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n    \n    if L == 2**n:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n\n    for i in range(n):\n        if (L >> i) & 1 == 0:\n            continue\n        \n        qc.x(i)\n        for j in range(i + 1, n):\n            if (L >> j) & 1 == 0:\n                qc.x(j)\n        \n        if i == n - 1:\n            qc.z(n - 1)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n\n        qc.x(i)\n        for j in range(i + 1, n):\n            if (L >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A16408BC857A1", "submission_order": 8, "result": "AC", "execution_time": "1673 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    if L == 2**n:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n\n    if n == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n\n    for i in range(n):\n        if (L >> i) & 1 == 0:\n            continue\n        \n        qc.x(i)\n        for j in range(i + 1, n):\n            if (L >> j) & 1 == 0:\n                qc.x(j)\n        \n        if i == n - 1:\n            qc.z(n - 1)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n\n        qc.x(i)\n        for j in range(i + 1, n):\n            if (L >> j) & 1 == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A17E742F07804", "submission_order": 1, "result": "DLE", "execution_time": "2528 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # for i in range(n):\n    #     qc.h(i)\n\n    for i in range(L):\n        # 2進数の配列に変換\n        b = list(map(int, list(format(i, \"0\"+str(n)+\"b\"))))\n        print(b)\n        for k in range(n):\n            if b[k] == 0:\n                qc.x(n-k-1)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for k in range(n):\n            if b[k] == 0:\n                qc.x(n-k-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A1BF4775FDEFF", "submission_order": 1, "result": "RE", "execution_time": "921 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A1BF4775FDEFF", "submission_order": 2, "result": "AC", "execution_time": "2656 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A1C668DE49944", "submission_order": 1, "result": "RE", "execution_time": "978 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    numbin = bin(L + (1<<n))[3:]\n    qc = QuantumCircuit(n)\n    numbin = numbin.rstrip(\"0\")\n    print(numbin)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n    qc1 = QuantumCircuit(n)\n    qc1.append(qc, range(n-1,-1,-1))\n    qc1 = qc1.decompose()\n    return qc1\n'''"}
{"problem": "QPC001_B4", "user": "A1C668DE49944", "submission_order": 2, "result": "AC", "execution_time": "1654 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    if L == (1<<n):\n        qc = QuantumCircuit(n)\n        return qc\n    numbin = bin(L + (1<<n))[3:]\n    qc = QuantumCircuit(n)\n    numbin = numbin.rstrip(\"0\")\n    print(numbin)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n    qc1 = QuantumCircuit(n)\n    qc1.append(qc, range(n-1,-1,-1))\n    qc1 = qc1.decompose()\n    return qc1\n'''"}
{"problem": "QPC001_B4", "user": "A1E502563CE91", "submission_order": 1, "result": "DLE", "execution_time": "1023 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef find_one_positions(n):\n    positions = []\n    position = 0\n\n    while n:\n        if n & 1:\n            positions.append(position)\n        n >>= 1\n        position += 1\n\n    return positions\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    neg_list = [0]*(2**n)\n    for i in range(L, 2**n):\n        print(neg_list)\n        pos1 = find_one_positions(i)\n        if neg_list[i] == 0: \n            if len(pos1) == 1:\n                qc.p(math.pi, pos1[0])\n            else:\n                qc.mcp(math.pi, pos1[1:], pos1[0])\n            for m in range(2**n):\n                pos1m = find_one_positions(m)\n                if all(elem in pos1m for elem in pos1):\n                    print(m)\n                    neg_list[m] = 1 - neg_list[m]\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A1E502563CE91", "submission_order": 2, "result": "RE", "execution_time": "1020 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef find_one_positions(n):\n    \"\"\"\n    Returns the positions of '1' bits in the binary representation of a natural number n.\n    The position is counted from the right, starting with 0.\n    \"\"\"\n    positions = []\n    position = 0\n\n    while n:\n        if n & 1:\n            positions.append(position)\n        n >>= 1\n        position += 1\n\n    return positions\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cnot(0, 1)\n    qc.h(1)\n\n    if L == 1:\n        for i in range(0, n, -1):\n            for j in range(i, n):\n                qc.x(j)\n            if i == n - 1:\n                qc.p(math.pi, i)\n            else:\n                qc.mcp(math.pi, list(range(i+1,n)), i)\n            for j in range(i, n):\n                qc.x(j)\n    else:\n        neg_list = [0]*(2**n)\n        for i in range(L, 2**n):\n            print(neg_list)\n            pos1 = find_one_positions(i)\n            if neg_list[i] == 0: \n                if len(pos1) == 1:\n                    qc.p(math.pi, pos1[0])\n                else:\n                    qc.mcp(math.pi, pos1[1:], pos1[0])\n                for m in range(2**n):\n                    pos1m = find_one_positions(m)\n                    if all(elem in pos1m for elem in pos1):\n                        print(m)\n                        neg_list[m] = 1 - neg_list[m]\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A1E502563CE91", "submission_order": 3, "result": "WA", "execution_time": "1036 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef find_one_positions(n):\n    \"\"\"\n    Returns the positions of '1' bits in the binary representation of a natural number n.\n    The position is counted from the right, starting with 0.\n    \"\"\"\n    positions = []\n    position = 0\n\n    while n:\n        if n & 1:\n            positions.append(position)\n        n >>= 1\n        position += 1\n\n    return positions\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    if L == 1:\n        for i in range(0, n, -1):\n            for j in range(i, n):\n                qc.x(j)\n            if i == n - 1:\n                qc.p(math.pi, i)\n            else:\n                qc.mcp(math.pi, list(range(i+1,n)), i)\n            for j in range(i, n):\n                qc.x(j)\n    else:\n        neg_list = [0]*(2**n)\n        for i in range(L, 2**n):\n            print(neg_list)\n            pos1 = find_one_positions(i)\n            if neg_list[i] == 0: \n                if len(pos1) == 1:\n                    qc.p(math.pi, pos1[0])\n                else:\n                    qc.mcp(math.pi, pos1[1:], pos1[0])\n                for m in range(2**n):\n                    pos1m = find_one_positions(m)\n                    if all(elem in pos1m for elem in pos1):\n                        print(m)\n                        neg_list[m] = 1 - neg_list[m]\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A2BF9B7F0995D", "submission_order": 1, "result": "DLE", "execution_time": "2480 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        for l in range(L):\n            if l & 1 == 0:\n                qc.x(0)\n            qc.z(0)\n            if l & 1 == 0:\n                qc.x(0)\n        return qc\n\n    for l in range(L):\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n        qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if (l >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A2CB91A2FEBF0", "submission_order": 1, "result": "RE", "execution_time": "2031 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply a multi-controlled Z gate for states 0 to L-1\n    # We will use a series of CNOT gates to create the effect of a multi-controlled Z gate\n    for i in range(L):\n        # Convert i to binary and apply CNOTs\n        binary_representation = format(i, f'0{n}b')  # Get binary representation of i with n bits\n        for j in range(n):\n            if binary_representation[j] == '1':\n                qc.x(j)  # Apply X gate to flip the qubit to |1> if needed\n        qc.h(n-1)  # Apply Hadamard to the last qubit to create superposition\n        qc.mct(list(range(n-1)), n-1)  # Apply multi-controlled Toffoli (mct) to flip the last qubit\n        qc.h(n-1)  # Apply Hadamard to the last qubit to revert it back\n        for j in range(n):\n            if binary_representation[j] == '1':\n                qc.x(j)  # Revert the X gates to restore original state\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A2CB91A2FEBF0", "submission_order": 2, "result": "AC", "execution_time": "2337 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Return an n-qubit circuit that multiplies the amplitudes of the basis\n    states |0>, |1>, …, |L-1> (little-endian integers) by −1 and leaves all\n    other amplitudes unchanged.  Global phase is ignored by the judge, so\n    nothing has to be done for L = 0 or L = 2**n.\n    The construction keeps the depth well below the required limit (≤ 50\n    for n ≤ 10).\n    \"\"\"\n    qc = QuantumCircuit(n)\n\n    total = 1 << n\n    if L == 0 or L == total:            # nothing to mark or global phase only\n        return qc\n\n    # Work from the most-significant bit (n−1) down to the least-significant.\n    #\n    # If the j-th bit of L is 1 we have to flip the sign of all states whose\n    #   – more-significant bits equal the prefix of L, and\n    #   – bit j equals 0.\n    #\n    # To realise a *positive* multi-controlled phase, every control must be\n    # in state |1>.  Hence, before applying the gate\n    #   – every control qubit whose prefix bit is 0 is flipped with X,\n    #   – the (would-be) target qubit j is also flipped so that the states\n    #     with bit j = 0 are mapped to |1>.\n    # After the controlled-Z the temporary X’s are undone.\n    #\n    for j in range(n - 1, -1, -1):              # j = MSB … LSB\n        if ((L >> j) & 1) == 0:                 # skip if that bit of L is 0\n            continue\n\n        # More-significant qubits (the prefix)\n        prefix = list(range(j + 1, n))\n        flipped_prefix = []                     # remember X’s to undo later\n\n        # 1) Bring every “0” of the prefix to “1” (positive control)\n        for k in prefix:\n            if ((L >> k) & 1) == 0:             # L’s prefix bit is 0\n                qc.x(k)\n                flipped_prefix.append(k)\n\n        # 2) Flip target qubit j so that ‘bit j = 0’ → |1>\n        qc.x(j)\n\n        # 3) Apply the multi-controlled Z  (all controls are now |1>)\n        if prefix:                              # at least one control\n            mcz = ZGate().control(len(prefix))  # all-ones ctrl_state\n            qc.append(mcz, prefix + [j])\n        else:                                   # j is the MSB → plain Z\n            qc.z(j)\n\n        # 4) Undo the X on the target qubit\n        qc.x(j)\n\n        # 5) Restore the prefix qubits that were flipped\n        for k in flipped_prefix:\n            qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A310E10829EAA", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L &= 1 << n\n\n    def rec(n: int, L: int, control: list[int]):\n        if n == 0:\n            return\n        nonlocal qc\n        i = n - 1\n        w = 1 << i\n        qc.append(XGate().control(len(control)), list(control) + [i])\n        rev = L >= w\n        if rev:\n            qc.append(ZGate().control(len(control)), list(control) + [i])\n            L -= w\n            qc.append(XGate().control(len(control)), list(control) + [i])\n        rec(i, L, control + [i])\n        if not rev:\n            qc.append(XGate().control(len(control)), list(control) + [i])\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A310E10829EAA", "submission_order": 2, "result": "WA", "execution_time": "919 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L &= 1 << n\n\n    def rec(n: int, L: int, control: list[int]):\n        if n == 0:\n            return\n        nonlocal qc\n        i = n - 1\n        w = 1 << i\n        qc.append(XGate().control(len(control)), list(control) + [i])\n        rev = L >= w\n        if rev:\n            qc.append(ZGate().control(len(control)), list(control) + [i])\n            L -= w\n            qc.append(XGate().control(len(control)), list(control) + [i])\n        rec(i, L, control + [i])\n        if not rev:\n            qc.append(XGate().control(len(control)), list(control) + [i])\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A310E10829EAA", "submission_order": 3, "result": "WA", "execution_time": "1035 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L &= 1 << n\n\n    def rec(n: int, L: int, control: list[int]):\n        if n == 0:\n            return\n        nonlocal qc\n        i = n - 1\n        w = 1 << i\n        def X():\n            nonlocal qc\n            if control:\n                qc.append(XGate().control(len(control)), list(control) + [i])\n            else:\n                qc.x(i)\n        def Z():\n            nonlocal qc\n            if control:\n                qc.append(ZGate().control(len(control)), list(control) + [i])\n            else:\n                qc.z(i)\n        X()\n        rev = L >= w\n        if rev:\n            Z()\n            L -= w\n            X()\n        rec(i, L, control + [i])\n        if not rev:\n            X()\n    \n    rec(n, L, [])\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A310E10829EAA", "submission_order": 4, "result": "AC", "execution_time": "2073 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L %= 1 << n\n\n    def rec(n: int, L: int, control: list[int]):\n        if n == 0:\n            return\n        nonlocal qc\n        i = n - 1\n        w = 1 << i\n        def X():\n            nonlocal qc\n            if control:\n                qc.append(XGate().control(len(control)), list(control) + [i])\n            else:\n                qc.x(i)\n        def Z():\n            nonlocal qc\n            if control:\n                qc.append(ZGate().control(len(control)), list(control) + [i])\n            else:\n                qc.z(i)\n        X()\n        rev = L >= w\n        if rev:\n            Z()\n            L -= w\n            X()\n        rec(i, L, control + [i])\n        if not rev:\n            X()\n    \n    rec(n, L, [])\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A32E052FC214C", "submission_order": 1, "result": "RE", "execution_time": "912 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 1, "result": "RE", "execution_time": "850 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        w = (1 << (n - i - 1))\n        if L & (1 << i) == 0:\n            controls = []\n            for k in range(i):\n                controls.append(k)\n            qc.mcp(math.pi, controls, i)\n            qc.x(i)\n    for i in reverse(range(n)):\n        w = (1 << (n - i - 1))\n        if L & (1 << i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 2, "result": "RE", "execution_time": "766 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        w = (1 << (n - i - 1))\n        if L & (1 << i) == 0:\n            controls = []\n            for k in range(i):\n                controls.append(k)\n            qc.mcp(math.pi, controls, i)\n            qc.x(i)\n    for i in reverse(range(n)):\n        w = (1 << (n - i - 1))\n        if L & (1 << i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 3, "result": "RE", "execution_time": "847 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        w = (1 << (n - i - 1))\n        if L & (1 << i) == 0:\n            controls = []\n            for k in range(i):\n                controls.append(k)\n            qc.mcp(math.pi, controls, i)\n            qc.x(i)\n    for i in reverse(range(n)):\n        w = (1 << (n - i - 1))\n        if L & (1 << i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 4, "result": "WA", "execution_time": "900 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        w = (1 << (n - i - 1))\n        if L & (1 << i) == 0:\n            controls = []\n            for k in range(i):\n                controls.append(k)\n            if len(controls) > 0:\n                qc.mcp(math.pi, controls, i)\n            qc.x(i)\n    for i in reversed(range(n)):\n        w = (1 << (n - i - 1))\n        if L & (1 << i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 5, "result": "WA", "execution_time": "954 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & (1 << i) == 0:\n            controls = []\n            for k in range(i):\n                controls.append(n-k-1)\n            if len(controls) > 0:\n                qc.mcp(math.pi, controls, n-i-1)\n            qc.x(n-i-1)\n    for i in reversed(range(n)):\n        if L & (1 << i) == 0:\n            qc.x(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 6, "result": "WA", "execution_time": "1054 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & (1 << i) == 0:\n            controls = []\n            for k in range(i):\n                controls.append(k)\n            if len(controls) > 0:\n                qc.mcp(math.pi, controls, i)\n            else:\n                qc.z(i)\n            qc.x(i)\n    for i in reversed(range(n)):\n        if L & (1 << i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 7, "result": "WA", "execution_time": "945 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & (1 << i) == 0:\n            controls = []\n            for k in range(i):\n                controls.append(n-k-1)\n            if len(controls) > 0:\n                qc.mcp(math.pi, controls, n-i-1)\n            else:\n                qc.z(n-i-1)\n            qc.x(n-i-1)\n    for i in reversed(range(n)):\n        if L & (1 << i) == 0:\n            qc.x(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 8, "result": "WA", "execution_time": "940 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        return qc\n    # 引く\n    L2 = (1 << n) - L\n    print(\"L2 = \", L2)\n    for i in range(n):\n        if L2 & (1 << (n - i - 1)) != 0:\n            print(\"i = \", i)\n            controls = []\n            for k in range(i):\n                controls.append(k)\n            if len(controls) > 0:\n                qc.mcp(math.pi, controls, i)\n            else:\n                qc.z(i)\n            qc.x(i)\n    for i in reversed(range(n)):\n        if L2 & (1 << (n - i - 1)) != 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3393D91CBB67", "submission_order": 9, "result": "AC", "execution_time": "2880 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        return qc\n    # 引く\n    L2 = (1 << n) - L\n    print(\"L2 = \", L2)\n    for i in range(n):\n        if L2 & (1 << (n - i - 1)) != 0:\n            print(\"i = \", i)\n            controls = []\n            for k in range(i):\n                controls.append(n-1-k)\n            if len(controls) > 0:\n                qc.mcp(math.pi, controls, n-1-i)\n            else:\n                qc.z(n-1-i)\n            qc.x(n-1-i)\n    for i in reversed(range(n)):\n        if L2 & (1 << (n - i - 1)) != 0:\n            qc.x(n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A35D91246E218", "submission_order": 1, "result": "WA", "execution_time": "861 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    def f(l: int, r: int, d: int):\n        # qc.barrier()\n        # print(l, r, d, li)\n        if d < 0 or r - l == 0:\n            return\n        N = 2 ** d\n        if r - l < N:\n            li.append(d)\n            f(l, r, d - 1)\n        else:\n            if d == n - 1:\n                qc.x(d)\n                qc.z(d)\n                qc.x(d)\n                f(l + N, r, d - 1)\n            else:\n                if len(li) > 0:\n                    qc.x(li)\n                qc.x(d)\n                qc.append(ZGate().control(n - d - 1), range(d, n))\n                if len(li) > 0:\n                    qc.x(li)\n                qc.x(d)\n                f(l + N, r, d - 1)\n\n    li = list()\n    f(0, L, n - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A35D91246E218", "submission_order": 2, "result": "AC", "execution_time": "2800 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    def f(l: int, r: int, d: int):\n        # qc.barrier()\n        # print(l, r, d, li)\n        if d < 0 or r - l == 0:\n            return\n        N = 2 ** d\n        if r - l < N:\n            li.append(d)\n            f(l, r, d - 1)\n        else:\n            if d == n - 1:\n                qc.x(d)\n                qc.z(d)\n                qc.x(d)\n                f(l + N, r, d - 1)\n            else:\n                if len(li) > 0:\n                    qc.x(li)\n                qc.x(d)\n                qc.append(ZGate().control(n - d - 1), range(d, n))\n                if len(li) > 0:\n                    qc.x(li)\n                qc.x(d)\n                f(l + N, r, d - 1)\n\n    li = list()\n    f(0, L, n - 1)\n    # |1111>を反転する\n    if 2 ** n == L:\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A369A87CB4565", "submission_order": 1, "result": "RE", "execution_time": "1528 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2*math.pi\n    for i in range(L-1):\n        qc.ry(theta, i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A369A87CB4565", "submission_order": 2, "result": "DLE", "execution_time": "1619 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 1, "result": "WA", "execution_time": "2095 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    mask = 2 ** (n - 1) - 1\n\n    qc.x(n-1)\n\n    for l in range(L):\n        if l >> (n - 1) != 0:\n            qc.x(n-1)\n        qc.append(ZGate().control(n-1, None, l & mask), range(n))\n        if l >> (n - 1) != 0:\n            qc.x(n-1)\n\n    qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 2, "result": "RE", "execution_time": "963 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    L -= 1\n\n    for i in reversed(range(n)):\n        if L & (1 << i) == 0:\n            continue\n\n        ctrl = 0\n        for j in range(i + 1, n):\n            ctrl |= 1 << (n - 1 - j)\n\n        qc.append(ZGate().control(n - 1 - i, None, ctrl),\n                  reversed(range(i, n)))\n        qc.x(i)\n        qc.append(ZGate().control(n - 1 - i, None, ctrl),\n                  reversed(range(i, n)))\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 3, "result": "WA", "execution_time": "1034 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    L -= 1\n\n    for i in reversed(range(1, n)):\n        if L & (1 << i) == 0:\n            continue\n\n        ctrl = 0\n        for j in range(i + 1, n):\n            ctrl |= 1 << (n - 1 - j)\n\n        print(\n            f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(i - 1, n)))}\")\n\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 4, "result": "WA", "execution_time": "1054 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    L -= 1\n\n    for i in reversed(range(1, n)):\n        if L & (1 << i) == 0:\n            continue\n\n        ctrl = 0\n        for j in range(i + 1, n):\n            if L & (1 << j) != 0:\n                ctrl |= 1 << (n - 1 - j)\n\n        print(\n            f\"nqubits={n-i}, ctrl={ctrl}, qubits={list(reversed(range(i - 1, n)))}\")\n\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n\n    ctrl = 0\n    for j in range(1, n):\n        if L & (1 << j) != 0:\n            ctrl |= 1 << (n - 1 - j)\n\n    if L & 1 != 0:\n        qc.x(0)\n    qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n    if L & 1 != 0:\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 5, "result": "WA", "execution_time": "848 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    L -= 1\n\n    for i in reversed(range(1, n)):\n        if L & (1 << i) == 0:\n            continue\n\n        ctrl = 0\n        for j in range(i + 1, n):\n            if L & (1 << j) != 0:\n                ctrl |= 1 << (n - 1 - j)\n\n        print(\n            f\"nqubits={n-i}, ctrl={ctrl}, qubits={list(reversed(range(i - 1, n)))}\")\n\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n\n    ctrl = 0\n    for j in range(1, n):\n        if L & (1 << j) != 0:\n            ctrl |= 1 << (n - 1 - j)\n\n    if L & 1 == 0:\n        qc.x(0)\n    print(\n        f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(i - 1, n)))}\")\n    qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n    if L & 1 == 0:\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 6, "result": "RE", "execution_time": "1337 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    if L == 1:\n        qc.x(n-1)\n        qc.append(ZGate().control(n-1, None, 0), range(n))\n        qc.x(n-1)\n        return qc\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    L -= 1\n\n    for i in reversed(range(1, n)):\n        if L & (1 << i) == 0:\n            continue\n\n        ctrl = 0\n        for j in range(i + 1, n):\n            if L & (1 << j) != 0:\n                ctrl |= 1 << (n - 1 - j)\n\n        print(\n            f\"nqubits={n-i}, ctrl={ctrl}, qubits={list(reversed(range(i - 1, n)))}, target={i - 1}\")\n\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n\n    ctrl = 0\n    for j in range(1, n):\n        if L & (1 << j) != 0:\n            ctrl |= 1 << (n - 1 - j)\n\n    qc.x(0)\n    print(\n        f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(n)))}\")\n    qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n    qc.x(0)\n\n    if L & 1 != 0:\n        print(\n            f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(n)))}\")\n        qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 7, "result": "WA", "execution_time": "1269 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n# from qiskit import Aer, transpile, execute\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    if L == 1:\n        qc.x(n-1)\n        qc.append(ZGate().control(n-1, None, 0), range(n))\n        qc.x(n-1)\n        return qc\n\n    L -= 1\n\n    for i in reversed(range(1, n)):\n        if L & (1 << i) == 0:\n            continue\n\n        ctrl = 0\n        for j in range(i + 1, n):\n            if L & (1 << j) != 0:\n                ctrl |= 1 << (n - 1 - j)\n\n        print(\n            f\"nqubits={n-i}, ctrl={ctrl}, qubits={list(reversed(range(i - 1, n)))}, target={i - 1}\")\n\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n\n    ctrl = 0\n    for j in range(1, n):\n        if L & (1 << j) != 0:\n            ctrl |= 1 << (n - 1 - j)\n\n    qc.x(0)\n    print(\n        f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(n)))}\")\n    qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n    qc.x(0)\n\n    if L & 1 != 0:\n        print(\n            f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(n)))}\")\n        qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 8, "result": "WA", "execution_time": "1076 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n# from qiskit import Aer, transpile, execute\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.z(0)\n        return qc\n\n    if L == 1:\n        qc.x(n-1)\n        qc.append(ZGate().control(n-1, None, 0), range(n))\n        qc.x(n-1)\n        return qc\n\n    L -= 1\n\n    for i in reversed(range(1, n)):\n        if L & (1 << i) == 0:\n            continue\n\n        ctrl = 0\n        for j in range(i + 1, n):\n            if L & (1 << j) != 0:\n                ctrl |= 1 << (n - 1 - j)\n\n        print(\n            f\"nqubits={n-i}, ctrl={ctrl}, qubits={list(reversed(range(i - 1, n)))}, target={i - 1}\")\n\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n\n    ctrl = 0\n    for j in range(1, n):\n        if L & (1 << j) != 0:\n            ctrl |= 1 << (n - 1 - j)\n\n    qc.x(0)\n    print(\n        f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(n)))}\")\n    qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n    qc.x(0)\n\n    if L & 1 != 0:\n        print(\n            f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(n)))}\")\n        qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A36AA47D286E8", "submission_order": 9, "result": "AC", "execution_time": "2465 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n# from qiskit import Aer, transpile, execute\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        if L == 2:\n            qc.z(0)\n        return qc\n\n    if L == 1:\n        qc.x(n-1)\n        qc.append(ZGate().control(n-1, None, 0), range(n))\n        qc.x(n-1)\n        return qc\n\n    L -= 1\n\n    for i in reversed(range(1, n)):\n        if L & (1 << i) == 0:\n            continue\n\n        ctrl = 0\n        for j in range(i + 1, n):\n            if L & (1 << j) != 0:\n                ctrl |= 1 << (n - 1 - j)\n\n        print(\n            f\"nqubits={n-i}, ctrl={ctrl}, qubits={list(reversed(range(i - 1, n)))}, target={i - 1}\")\n\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n        qc.append(ZGate().control(n - i, None, ctrl),\n                  reversed(range(i - 1, n)))\n        qc.x(i - 1)\n\n    ctrl = 0\n    for j in range(1, n):\n        if L & (1 << j) != 0:\n            ctrl |= 1 << (n - 1 - j)\n\n    qc.x(0)\n    print(\n        f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(n)))}\")\n    qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n    qc.x(0)\n\n    if L & 1 != 0:\n        print(\n            f\"nqubits={n-1}, ctrl={ctrl}, qubits={list(reversed(range(n)))}\")\n        qc.append(ZGate().control(n-1, None, ctrl), reversed(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A37982A0CBE93", "submission_order": 1, "result": "AC", "execution_time": "2839 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #For each group\n    for i in range(n):\n        #if ith bit of l is 0, no ZGate\n        if not ((L >> i) & 1):\n            continue\n        #subset[i] < l[i] so subset[i] == 0\n        qc.x(i)\n\n        #get ready for CZGate\n        for j in range(i+1, n):\n            #if j (>i) th bit of l is 0, flip bit\n            if not ((L >> j) & 1):\n                qc.x(j)\n\n        #For last subset which has no control bit\n        if i == n - 1:\n            qc.z(i)\n        else:\n            #Apply CZGate that is in the subset\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n\n        #Reverse the preparation\n        qc.x(i)\n        for j in range(i+1, n):\n            #if j (>i) th bit of l is 0, flip bit\n            if not ((L >> j) & 1):\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A3E1BF81F4F76", "submission_order": 1, "result": "AC", "execution_time": "1662 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if (L>>(n-1))%2==0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        if (L>>i)%2==0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            qc.mcp(math.pi, list(range(i+1,n)), i)\n            qc.x(i)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A42D43648C5C1", "submission_order": 1, "result": "WA", "execution_time": "1333 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  if L == (1 << n):\n    for i in range(n):\n      qc.z(i)\n  else:\n    for i in range(n):\n      qc.x(i)\n    for i in range(n - 1, -1, -1):\n      if ((L >> i) & 1) == 1:\n        print(i)\n        if i == n - 1:\n          qc.z(n - 1)\n        else:\n          qc.append(ZGate().control(n - 1 - i), range(i, n))\n        qc.x(i)\n    for i in range(n):\n      if ((L >> i) & 1) == 0:\n        qc.x(i)\n  return qc\n'''"}
{"problem": "QPC001_B4", "user": "A42D43648C5C1", "submission_order": 2, "result": "WA", "execution_time": "1025 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  if L == (1 << n):\n    for i in range(n):\n      qc.z(i)\n  else:\n    for i in range(n):\n      qc.x(i)\n    for i in range(n - 1, -1, -1):\n      if ((L >> i) & 1) == 1:\n        if i == n - 1:\n          qc.z(n - 1)\n        else:\n          qc.append(ZGate().control(n - 1 - i), range(i, n))\n        qc.x(i)\n    for i in range(n):\n      if ((L >> i) & 1) == 0:\n        qc.x(i)\n  return qc\n'''"}
{"problem": "QPC001_B4", "user": "A42D43648C5C1", "submission_order": 3, "result": "AC", "execution_time": "2033 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  if L < (1 << n):\n    for i in range(n):\n      qc.x(i)\n    for i in range(n - 1, -1, -1):\n      if ((L >> i) & 1) == 1:\n        if i == n - 1:\n          qc.z(n - 1)\n        else:\n          qc.append(ZGate().control(n - 1 - i), range(i, n))\n        qc.x(i)\n    for i in range(n):\n      if ((L >> i) & 1) == 0:\n        qc.x(i)\n  return qc\n'''"}
{"problem": "QPC001_B4", "user": "A43201A5E45AD", "submission_order": 1, "result": "AC", "execution_time": "2047 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n<3:\n        for l in range(L):\n        # print(l)\n        # i=0\n            for i in range(n):\n                if not (1<<i)&l:\n                    qc.x(i)\n                    # print(\"i=\",i)\n            if n>1:\n                qc.h(0)\n                qc.mcx(list(range(1,n)),0)\n                qc.h(0)\n            else:\n                qc.z(0)\n            \n            for i in range(n):\n                if not (1<<i)&l:\n                    qc.x(i)\n        return qc\n    l=L-1\n    for i in range(n):\n        if not (1<<i)&l:\n            qc.x(i)\n            # print(\"i=\",i)\n    qc.h(0)\n    qc.mcx(list(range(1,n)),0)\n    qc.h(0)\n    \n    for i in range(n):\n        if not (1<<i)&l:\n                qc.x(i)\n\n    j=0\n    while j<n:\n        print(\"l1=\",l)\n        print(\"j1=\",j)\n        if l%2==0:\n            l=l//2\n            j+=1\n            continue\n        l=l-1\n        # j+=1\n        print(\"l=\",l)\n        print(\"j=\",j)\n        for i in range(n-j):\n            if not (1<<i)&l:\n                qc.x(i+j)\n                # print(\"i=\",i)\n        print(n,j)\n        if j+1<n:\n            qc.h(j)\n            print(list(range(j+1,n)),j)\n            qc.mcx(list(range(j+1,n)),j)\n            qc.h(j)\n        else:\n            qc.z(j)\n        for i in range(n-j):\n            if not (1<<i)&l:\n                qc.x(i+j)\n                # print(\"i=\",i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A43BC94A4695C", "submission_order": 1, "result": "RE", "execution_time": "1022 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i)&1==0:\n            continue\n        for j in range(i,n):\n            if (L>>j)&1==0:\n                qc.x(j)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(i,n))\n        for j in range(i,n):\n            if (L>>j)&1==0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A43BC94A4695C", "submission_order": 2, "result": "RE", "execution_time": "1094 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from qiskit.circuit.library import ZGate\n    for i in range(n):\n        if (L>>i)&1==0:\n            continue\n        for j in range(i,n):\n            if (L>>j)&1==0:\n                qc.x(j)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(i,n))\n        for j in range(i,n):\n            if (L>>j)&1==0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 1, "result": "WA", "execution_time": "922 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   if n != 1:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            # if ctrlarg[i-1] == '1':\n            #    qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            # if ctrlarg[i-1] == '1':\n            #    qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n\n   \n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n      \n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 2, "result": "WA", "execution_time": "828 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   if n != 1:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n\n   \n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n      \n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 3, "result": "WA", "execution_time": "1017 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   if n != 1:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      qc.h(range(n))\n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n\n\n   \n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 4, "result": "WA", "execution_time": "991 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   if n != 1:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n\n\n   \n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 5, "result": "WA", "execution_time": "1169 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   if n != 1 and 2**n != L:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n   elif 2**n == L:\n      qc.x(0)\n      qc.x(0)\n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n   # for i in range(n//2):\n   #      qc.swap(i, n - 1 - i)\n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 6, "result": "WA", "execution_time": "992 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   if n != 1 and 2**n != L:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      #qc.h(range(n))\n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n   elif 2**n == L:\n      qc.x(0)\n      qc.x(0)\n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 7, "result": "WA", "execution_time": "1772 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n   if n != 1 and 2**n != L:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      \n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n   elif 2**n == L:\n      qc.x(0)\n      qc.x(0)\n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 8, "result": "WA", "execution_time": "1145 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   if n != 1 and 2**n != L:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n\n      for i in range(n//2):\n         qc.swap(i, n - 1 - i)\n      \n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n      for i in range(n//2):\n         qc.swap(i, n - 1 - i)\n   elif 2**n == L and n != 1:\n      qc.x(0)\n      qc.x(0)\n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n   \n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 9, "result": "WA", "execution_time": "958 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n   if n != 1 and 2**n != L:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      \n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n   elif 2**n == L and n != 1:\n      qc.x(0)\n      qc.x(0)\n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 10, "result": "WA", "execution_time": "1090 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n   if n != 1 and 2**n != L:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      \n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n   elif 2**n == L and n != 1:\n      qc.x(0)\n      qc.x(0)\n   else:\n      if L == 2:\n         qc.z(0)\n         \n\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4423F6FAD84D", "submission_order": 11, "result": "AC", "execution_time": "2216 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCMT\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ctrlarg = []\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n   if n != 1 and 2**n != L:\n      strL = bin(L)\n      strL = strL[2:]\n      while len(strL) < n:\n         strL = '0'  + strL   \n      print(strL)\n      \n      for i in range(len(strL)):\n         if i > 0:\n            print(i)\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            qc.append(ZGate().control(i), qargs=[j for j in range(i+1)])\n            for ind in range(len(ctrlarg)):\n               if ctrlarg[ind] == '0':\n                  qc.x(ind)\n            if ctrlarg[i-1] == '1':\n               qc.x(i)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n         else:\n            print(i)\n            qc.z(0)\n            ctrlarg.append(strL[i])\n            if '1' not in strL[i+1:]:\n               break\n   elif 2**n == L and n != 1:\n      qc.x(0)\n      qc.x(0)\n   else:\n      if L == 1:\n         qc.z(0)\n         \n\n   for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n   # Write your code here:\n\n   return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4437D341C2C2", "submission_order": 1, "result": "RE", "execution_time": "825 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=[]\n    for i in range(n-1,-1,-1):\n        l.append(i)\n        if (1<<i)<=L:\n            qc.x(i)\n            qc.append(GlobalPhaseGate(phase=math.pi).control(len(l)), l)\n            qc.x(i)\n            L-=(1<<i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4437D341C2C2", "submission_order": 2, "result": "WA", "execution_time": "1181 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=[]\n    for i in range(n-1,-1,-1):\n        l.append(i)\n        if (1<<i)<=L:\n            qc.x(i)\n            qc.append(GlobalPhaseGate(phase=math.pi).control(len(l)), l)\n            qc.x(i)\n            L-=(1<<i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4437D341C2C2", "submission_order": 3, "result": "AC", "execution_time": "1836 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=[]\n    t=[]\n    for i in range(n-1,-1,-1):\n        j=i\n        l.append(j)\n        if (1<<i)>=L:\n            qc.append(GlobalPhaseGate(phase=math.pi).control(len(l)), l)\n            qc.x(j)\n            t.append(j)\n        else:\n            L-=(1<<i)\n\n    for j in t:\n        qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A481C9149C381", "submission_order": 1, "result": "WA", "execution_time": "1212 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      if L == 2:\n        qc.z(0)\n      return qc\n\n    flip = list()\n    for i in reversed(range(n)):\n        flip.append( L // 2**(i) )\n        L = L % 2**(i)\n\n    print(flip)\n    if flip[0]:\n      qc.x(n-1)\n      qc.z(n-1)\n      qc.x(n-1)\n    \n    for i in range(1,n):\n      if flip[i]:\n        for j in range(i-1):\n          if not flip[j]:\n            qc.x(n-1-j)\n        qc.x(n-1-i)\n        qc.append(ZGate().control(i), range(n-1-i,n))\n        for j in range(i-1):\n          if not flip[j]:\n            qc.x(n-1-j)\n        qc.x(n-1-i)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A481C9149C381", "submission_order": 2, "result": "WA", "execution_time": "1134 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      if L == 2:\n        qc.z(0)\n      return qc\n    \n    if L == 2**n:\n      return qc\n\n    flip = list()\n    for i in reversed(range(n)):\n        flip.append( L // 2**(i) )\n        L = L % 2**(i)\n\n    print(flip)\n    if flip[0]:\n      qc.x(n-1)\n      qc.z(n-1)\n      qc.x(n-1)\n    \n    for i in range(1,n):\n      if flip[i]:\n        for j in range(i-1):\n          if not flip[j]:\n            qc.x(n-1-j)\n        qc.x(n-1-i)\n        qc.append(ZGate().control(i), range(n-1-i,n))\n        for j in range(i-1):\n          if not flip[j]:\n            qc.x(n-1-j)\n        qc.x(n-1-i)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A481C9149C381", "submission_order": 3, "result": "AC", "execution_time": "2196 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if n == 1:\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      if L == 2:\n        qc.z(0)\n      return qc\n    \n    if L == 2**n:\n      return qc\n\n    flip = list()\n    for i in reversed(range(n)):\n        flip.append( L // 2**(i) )\n        L = L % 2**(i)\n\n    print(flip)\n    if flip[0]:\n      qc.x(n-1)\n      qc.z(n-1)\n      qc.x(n-1)\n    \n    for i in range(1,n):\n      if flip[i]:\n        for j in range(i):\n          if not flip[j]:\n            qc.x(n-1-j)\n        qc.x(n-1-i)\n        qc.append(ZGate().control(i), range(n-1-i,n))\n        for j in range(i):\n          if not flip[j]:\n            qc.x(n-1-j)\n        qc.x(n-1-i)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A49C174C35D20", "submission_order": 1, "result": "RE", "execution_time": "888 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        if (((L - 1) >> i) & 1):\n            qc.x(i)\n            if i == n - 1:\n                qc.z(i)\n            else:\n                controls = list(range(i + 1, n))\n                cz_gate = ZGate().control(len(controls))\n                qc.append(cz_gate, controls + [i])\n            qc.x(i)\n        else:\n            qc.x(i)\n\n    controls = list(range(1, n))\n    cz_gate = ZGate().control(len(controls))\n    qc.append(cz_gate, controls + [0])\n\n    for i in range(n - 1, -1, -1):\n        if not (((L - 1) >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A49C174C35D20", "submission_order": 2, "result": "RE", "execution_time": "740 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        if (((L - 1) >> i) & 1):\n            qc.x(i)\n            if i == n - 1:\n                qc.z(i)\n            else:\n                controls = list(range(i + 1, n))\n                cz_gate = ZGate().control(len(controls))\n                qc.append(cz_gate, controls + [i])\n            qc.x(i)\n        else:\n            qc.x(i)\n\n    controls = list(range(1, n))\n    cz_gate = ZGate().control(len(controls))\n    qc.append(cz_gate, controls + [0])\n\n    for i in range(n - 1, -1, -1):\n        if not (((L - 1) >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A49C174C35D20", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        if (((L - 1) >> i) & 1):\n            qc.x(i)\n            if i == n - 1:\n                qc.z(i)\n            else:\n                controls = list(range(i + 1, n))\n                cz_gate = ZGate().control(len(controls))\n                qc.append(cz_gate, controls + [i])\n            qc.x(i)\n        else:\n            qc.x(i)\n\n    if n > 1:\n        controls = list(range(1, n))\n        cz_gate = ZGate().control(len(controls))\n        qc.append(cz_gate, controls + [0])\n    else:\n        qc.z(0)\n\n    for i in range(n - 1, -1, -1):\n        if not (((L - 1) >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 1, "result": "WA", "execution_time": "993 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(n-1,-1,-1):\n\n        lst = []\n        for j in range(i+1,n):\n            lst.append(j)\n            if (L>>j)&1:\n                pass\n            else:\n                qc.x(j)\n\n        if len(lst)==0:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n        else:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.append(MCMT('z', len(lst), 1), lst+[i])\n                qc.x(i)\n\n        for j in range(i+1,n):\n            lst.append(j)\n            if (L>>j)&1:\n                pass\n            else:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 2, "result": "UGE", "execution_time": "1016 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n\n    for i in range(n-1,-1,-1):\n\n        lst = []\n        for j in range(i+1,n):\n            lst.append(j)\n            if (L>>j)&1:\n                pass\n            else:\n                qc.x(j)\n\n        if len(lst)==0:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n        else:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.append(MCMT('z', len(lst), 1), lst+[i])\n                qc.x(i)\n\n        for j in range(i+1,n):\n            lst.append(j)\n            if (L>>j)&1:\n                pass\n            else:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 3, "result": "UGE", "execution_time": "942 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    import math\n    from qiskit.circuit.library import MCMT\n    # for i in range(n):\n    #     qc.h(i)\n\n    for i in range(n-1,-1,-1):\n\n        lst = []\n        for j in range(i+1,n):\n            lst.append(j)\n            if (L>>j)&1:\n                pass\n            else:\n                qc.x(j)\n\n        if len(lst)==0:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n        else:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.append(MCMT('z', len(lst), 1), lst+[i])\n                qc.x(i)\n\n        for j in range(i+1,n):\n            lst.append(j)\n            if (L>>j)&1:\n                pass\n            else:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 4, "result": "UGE", "execution_time": "939 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    ato = []\n    for i in range(n-1,-1,-1):\n        qc.barrier()\n        lst = []\n        for j in range(i+1,n):\n            lst.append(j)\n            # if (L>>j)&1:\n            #     pass\n            # else:\n            #     qc.x(j)\n\n        if len(lst)==0:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.append(MCMT('z', len(lst), 1), lst+[i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n        # for j in range(i+1,n):\n        #     lst.append(j)\n            # if (L>>j)&1:\n            #     pass\n            # else:\n            #     qc.x(j)\n        for i in ato:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 5, "result": "WA", "execution_time": "1128 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    ato = []\n    for i in range(n-1,-1,-1):\n        # qc.barrier()\n        lst = []\n        for j in range(i+1,n):\n            lst.append(j)\n            # if (L>>j)&1:\n            #     pass\n            # else:\n            #     qc.x(j)\n\n        if len(lst)==0:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.append(MCMT('z', len(lst), 1), lst+[i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n        # for j in range(i+1,n):\n        #     lst.append(j)\n            # if (L>>j)&1:\n            #     pass\n            # else:\n            #     qc.x(j)\n        for i in ato:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 6, "result": "UGE", "execution_time": "924 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    ato = []\n    for i in range(n-1,-1,-1):\n        # qc.barrier()\n        lst = []\n        for j in range(i+1,n):\n            lst.append(j)\n            # if (L>>j)&1:\n            #     pass\n            # else:\n            #     qc.x(j)\n\n        if len(lst)==0:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.append(MCMT('z', len(lst), 1), lst+[i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n        # for j in range(i+1,n):\n        #     lst.append(j)\n            # if (L>>j)&1:\n            #     pass\n            # else:\n            #     qc.x(j)\n    for i in ato:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 7, "result": "RE", "execution_time": "757 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = [0]\n        qc.append(MCMT('z', len(lst), 1), lst+[i])\n    #     # qc.barrier()\n    #     lst = []\n    #     for j in range(i+1,n):\n    #         lst.append(j)\n    #         # if (L>>j)&1:\n    #         #     pass\n    #         # else:\n    #         #     qc.x(j)\n\n    #     if len(lst)==0:\n    #         if (L>>i)&1:\n    #             qc.x(i)\n    #             qc.z(i)\n    #             qc.x(i)\n    #         else:\n    #             qc.x(i)\n    #             ato.append(i)\n    #     else:\n    #         if (L>>i)&1:\n    #             qc.x(i)\n    #             qc.append(MCMT('z', len(lst), 1), lst+[i])\n    #             qc.x(i)\n    #         else:\n    #             qc.x(i)\n    #             ato.append(i)\n\n    #     # for j in range(i+1,n):\n    #     #     lst.append(j)\n    #         # if (L>>j)&1:\n    #         #     pass\n    #         # else:\n    #         #     qc.x(j)\n    # for i in ato:\n    #     qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 8, "result": "RE", "execution_time": "979 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    lst = [0]\n    qc.append(MCMT('z', len(lst), 1), lst+[1])\n    # for i in range(n):\n    #     qc.h(i)\n    # ato = []\n    # for i in range(n-1,-1,-1):\n    #     lst = [0]\n    #     qc.append(MCMT('z', len(lst), 1), lst+[i])\n    #     # qc.barrier()\n    #     lst = []\n    #     for j in range(i+1,n):\n    #         lst.append(j)\n    #         # if (L>>j)&1:\n    #         #     pass\n    #         # else:\n    #         #     qc.x(j)\n\n    #     if len(lst)==0:\n    #         if (L>>i)&1:\n    #             qc.x(i)\n    #             qc.z(i)\n    #             qc.x(i)\n    #         else:\n    #             qc.x(i)\n    #             ato.append(i)\n    #     else:\n    #         if (L>>i)&1:\n    #             qc.x(i)\n    #             qc.append(MCMT('z', len(lst), 1), lst+[i])\n    #             qc.x(i)\n    #         else:\n    #             qc.x(i)\n    #             ato.append(i)\n\n    #     # for j in range(i+1,n):\n    #     #     lst.append(j)\n    #         # if (L>>j)&1:\n    #         #     pass\n    #         # else:\n    #         #     qc.x(j)\n    # for i in ato:\n    #     qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 9, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    ato = []\n    for i in range(n-1,-1,-1):\n        # qc.barrier()\n        lst = []\n        for j in range(i+1,n):\n            lst.append(j)\n\n        if len(lst)==0:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A4B7DB3F01EC6", "submission_order": 10, "result": "AC", "execution_time": "1982 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import MCPhaseGate\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    ato = []\n    for i in range(n-1,-1,-1):\n        # qc.barrier()\n        lst = []\n        for j in range(i+1,n):\n            lst.append(j)\n\n        if len(lst)==0:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L>>i)&1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5006634B56CD", "submission_order": 1, "result": "RE", "execution_time": "905 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1 and L==1\n            qc.z(i)\n    else:\n        control_history = []\n        for num in range(L,pow(2,n)):\n            binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n            binary_list = [int(bit) for bit in binary_string[::-1]]\n            control_qubits = []\n            counter = 0\n            flag = 0\n            all_qubits = []\n            for i in range(n):\n                all_qubits.append(i)\n\n            for b in binary_list:\n                if b==1:\n                    control_qubits.append(counter)\n                    counter+=1\n                else:\n                    counter+=1\n            if not(control_qubits in control_history):\n                print(control_qubits)\n                if len(control_qubits) -1 != 0:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                else:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5006634B56CD", "submission_order": 2, "result": "DLE", "execution_time": "2114 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1 and L==1:\n            qc.z(0)\n    else:\n        control_history = []\n        for num in range(L,pow(2,n)):\n            binary_string = bin(num)[2:]  # Convert to binary and remove the '0b' prefix\n            binary_list = [int(bit) for bit in binary_string[::-1]]\n            control_qubits = []\n            counter = 0\n            flag = 0\n            all_qubits = []\n            for i in range(n):\n                all_qubits.append(i)\n\n            for b in binary_list:\n                if b==1:\n                    control_qubits.append(counter)\n                    counter+=1\n                else:\n                    counter+=1\n            if not(control_qubits in control_history):\n                print(control_qubits)\n                if len(control_qubits) -1 != 0:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                else:\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                    cz_gate = ZGate().control(len(all_qubits)-1)\n                    qc.append(cz_gate, all_qubits)\n                    for i in range(n):\n                        if not i in control_qubits:\n                            qc.x(i)\n                control_history.append(control_qubits)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A50390B769AB3", "submission_order": 1, "result": "DLE", "execution_time": "1739 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    A = []\n    B = [1] * (2 ** n) \n    for i in range(2**n):\n      A += [(i.bit_count(),i)]\n    A.sort()\n    for (_,i) in A:\n      tgt = -1\n      if i < L:\n        tgt = 1\n      if tgt != B[i]:\n        l = []\n        for b in range(n):\n          if (i & (1 << b)) > 0:\n            l += [b]\n        if len(l) == 1:\n          qc.z(l[0])\n        else:\n          qc.append(ZGate().control(len(l) - 1), l)\n        for b in range(2**n):\n          if (i & b) == i:\n            B[b] *= -1\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A50390B769AB3", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "97 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    A = []\n    B = [1] * (2 ** n) \n    for i in range(2**n):\n      A += [(i.bit_count(),i)]\n    A.sort()\n    for (_,i) in A:\n      tgt = -1\n      if i < L:\n        tgt = 1\n      if tgt != B[i]:\n        l = []\n        for b in range(n):\n          if (i & (1 << b)) > 0:\n            l += [b]\n        if len(l) == 1:\n          qc.z(l[0])\n        else:\n          qc.append(ZGate().control(len(l) - 1), l)\n        for b in range(2**n):\n          if (i & b) == i:\n            B[b] *= -1\n    if qc.depth() <= 50:\n      return qc\n    qc = QuantumCircuit(n)\n    for i in range(n):\n      qc.x(i)\n    A = []\n    B = [-1] * (2 ** n) \n    for i in range(2**n):\n      A += [(i.bit_count(),i)]\n    A.sort()\n    for (_,i) in A:\n      tgt = -1\n      if (i^(2**n-1)) < L:\n        tgt = 1\n      if tgt != B[i]:\n        l = []\n        for b in range(n):\n          if (i & (1 << b)) > 0:\n            l += [b]\n        if len(l) == 1:\n          qc.z(l[0])\n        else:\n          qc.append(ZGate().control(len(l) - 1), l)\n        for b in range(2**n):\n          if (i & b) == i:\n            B[b] *= -1\n    for i in range(n):\n      qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A50390B769AB3", "submission_order": 3, "result": "RE", "execution_time": "860 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.x(i)\n    A = []\n    B = [-1] * (2 ** n) \n    for i in range(2**n):\n      A += [(i.bit_count(),i)]\n    A.sort()\n    for (_,i) in A:\n      tgt = -1\n      if (i^(2**n-1)) < L:\n        tgt = 1\n      if tgt != B[i]:\n        l = []\n        for b in range(n):\n          if (i & (1 << b)) > 0:\n            l += [b]\n        if len(l) == 1:\n          qc.z(l[0])\n        else:\n          qc.append(ZGate().control(len(l) - 1), l)\n        for b in range(2**n):\n          if (i & b) == i:\n            B[b] *= -1\n    for i in range(n):\n      qc.x(i)\n    \n    if qc.depth() <= 50:\n      return qc\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    A = []\n    B = [1] * (2 ** n) \n    for i in range(2**n):\n      A += [(i.bit_count(),i)]\n    A.sort()\n    for (_,i) in A:\n      tgt = -1\n      if i < L:\n        tgt = 1\n      if tgt != B[i]:\n        l = []\n        for b in range(n):\n          if (i & (1 << b)) > 0:\n            l += [b]\n        if len(l) == 1:\n          qc.z(l[0])\n        else:\n          qc.append(ZGate().control(len(l) - 1), l)\n        for b in range(2**n):\n          if (i & b) == i:\n            B[b] *= -1\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A50390B769AB3", "submission_order": 4, "result": "AC", "execution_time": "2997 ms", "memory": "98 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.x(i)\n    A = []\n    B = [-1] * (2 ** n) \n    for i in range(2**n):\n      A += [(i.bit_count(),i)]\n    A.sort()\n    ok = 1\n    for (_,i) in A:\n      tgt = -1\n      if (i^(2**n-1)) < L:\n        tgt = 1\n      if tgt != B[i]:\n        l = []\n        for b in range(n):\n          if (i & (1 << b)) > 0:\n            l += [b]\n        if len(l) == 0:\n          ok = 0\n          break\n        if len(l) == 1:\n          qc.z(l[0])\n        else:\n          qc.append(ZGate().control(len(l) - 1), l)\n        for b in range(2**n):\n          if (i & b) == i:\n            B[b] *= -1\n    for i in range(n):\n      qc.x(i)\n    \n    if qc.depth() <= 50 and ok == 1:\n      return qc\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    A = []\n    B = [1] * (2 ** n) \n    for i in range(2**n):\n      A += [(i.bit_count(),i)]\n    A.sort()\n    for (_,i) in A:\n      tgt = -1\n      if i < L:\n        tgt = 1\n      if tgt != B[i]:\n        l = []\n        for b in range(n):\n          if (i & (1 << b)) > 0:\n            l += [b]\n        if len(l) == 1:\n          qc.z(l[0])\n        else:\n          qc.append(ZGate().control(len(l) - 1), l)\n        for b in range(2**n):\n          if (i & b) == i:\n            B[b] *= -1\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5263B470B399", "submission_order": 1, "result": "DLE", "execution_time": "2248 ms", "memory": "97 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n#def solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    dp = [-1 for _ in range(2**n)]\n    for i in range(2**n):\n        if i >= L:\n            if dp[i] == -1:\n                array = []\n                for j in range(n):\n                    if i & (1 << j) != 0:\n                        array.append(j)\n                if len(array) == 1:\n                    qc.z(array[0])\n                else:\n                    qc.append(ZGate().control(len(array) - 1), array)\n                for j in range(2**n):\n                    if j > i:\n                        ok = True\n                        for k in range(n):\n                            if ((i & (1 << k)) != 0) and ((j & (1 << k)) == 0):\n                                ok = False\n                        if ok:\n                            dp[j] *= -1\n\n\n\n\n    #qc.append(ZGate(), [1])\n    #qc.append(ZGate().control(1), [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5263B470B399", "submission_order": 2, "result": "WA", "execution_time": "1000 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n#def solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    dp = [-1 for _ in range(2**n)]\n    for i in range(2**n):\n        if i % 2 == 1:\n            dp[i] = 1\n    for i in range(2**n):\n        if i >= L:\n            if dp[i] == -1:\n                array = []\n                for j in range(n):\n                    if i & (1 << j) != 0:\n                        array.append(j)\n                if len(array) == 1:\n                    qc.z(array[0])\n                else:\n                    qc.append(ZGate().control(len(array) - 1), array)\n                for j in range(2**n):\n                    if j > i:\n                        ok = True\n                        for k in range(n):\n                            if ((i & (1 << k)) != 0) and ((j & (1 << k)) == 0):\n                                ok = False\n                        if ok:\n                            dp[j] *= -1\n\n\n\n\n    #qc.append(ZGate(), [1])\n    #qc.append(ZGate().control(1), [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A53B6196E75D5", "submission_order": 1, "result": "AC", "execution_time": "2485 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    #for i in range(n):\n    #    qc.h(i)\n\n    L -= 1\n\n    s0 = 1\n    if not (L >> (n - 1)) & 1:\n        qc.x(n - 1)\n        qc.z(n - 1)\n        qc.x(n - 1)\n        s0 = 0\n\n    s = ''\n    for i in range(n - 2, -1, -1):\n        if not (L >> i) & 1:\n            if s0 == 0:\n                qc.x(n - 1)\n            qc.append(ZGate().control(n - i - 1, ctrl_state=s+'1'), range(i, n))\n            if s0 == 0:\n                qc.x(n - 1)\n        s += str((L >> i) & 1)\n    #print(s)\n\n    #qc.append(ZGate().control(n - 1, ctrl_state='01'), range(n))\n    #qc.z(n - 1)\n    #qc.x(n - 1)\n    #qc.append(ZGate().control(n - 2, ctrl_state='11'), range(1, n))\n    #qc.x(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A53E97F0285B8", "submission_order": 1, "result": "DLE", "execution_time": "1469 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    # 必要な量子ビットの数を計算\n    num_qubits = max(n, math.ceil(math.log2(L+1)))\n    qc = QuantumCircuit(num_qubits)\n\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            # 1量子ビットの場合、通常のZゲートを使用\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A56469CEF53C9", "submission_order": 1, "result": "RE", "execution_time": "1320 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n                \n        qc.x(i)\n        \n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        \n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A56469CEF53C9", "submission_order": 2, "result": "WA", "execution_time": "1537 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n                \n        qc.x(i)\n        \n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        \n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A56469CEF53C9", "submission_order": 3, "result": "AC", "execution_time": "1816 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n                \n        qc.x(i)\n        \n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5914F0BFE942", "submission_order": 1, "result": "RE", "execution_time": "1957 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rz(2*math.pi, i)\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5914F0BFE942", "submission_order": 2, "result": "RE", "execution_time": "1797 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rz(2*math.pi, i)\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5914F0BFE942", "submission_order": 3, "result": "RE", "execution_time": "1852 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rz(2*math.pi, i)\n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5914F0BFE942", "submission_order": 4, "result": "RE", "execution_time": "2061 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.rz(2*math.pi, 0)\n    qc.append(ZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 1, "result": "DLE", "execution_time": "2262 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 2, "result": "RE", "execution_time": "1660 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not(L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(n))\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 3, "result": "RE", "execution_time": "1889 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not(L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(n))\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 4, "result": "WA", "execution_time": "1783 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i >= L.bit_length() or not(L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 5, "result": "WA", "execution_time": "1520 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not(L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 6, "result": "WA", "execution_time": "1488 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i >= L.bit_length() or not(L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 7, "result": "RE", "execution_time": "1388 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i >= L.bit_length() or not(L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i + 1, n))\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 8, "result": "WA", "execution_time": "1817 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not(L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not(L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        for j in range(i + 1, n):\n            if not(L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5BFB38637FC1", "submission_order": 9, "result": "AC", "execution_time": "2200 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not(L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not(L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        for j in range(i + 1, n):\n            if not(L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5CD30F08C643", "submission_order": 1, "result": "AC", "execution_time": "2905 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    print(bitrep)\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        print(mask)\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef solve(n: int, l: int):\n    regin = QuantumRegister(n)\n    qc = QuantumCircuit(regin)\n\n    anc = QuantumRegister(1)\n    qc.add_register(anc)\n\n    qc.x(anc)\n    qc.h(anc)\n\n    qc.compose(oracle_less(n, l), inplace=True)\n\n    qc.h(anc)\n    qc.x(anc)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A5CD8DF1431A5", "submission_order": 1, "result": "RE", "execution_time": "779 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qreg = QuantumRegister(n)\n    circuit = QuantumCircuit(qreg)\n\n\n    most_bit = int(math.log2(L)) + 1\n\n    circuit.x(qreg[most_bit])\n    circuit.z(qreg[most_bit])\n    circuit.x(qreg[most_bit])\n\n\n\n    for i in range(2**(most_bit-1)+1, L):\n        bin_state = format(i, f'0{n}b')[::-1]\n\n        x_gates = [idx for idx, bit in enumerate(bin_state) if bit == '0']\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n        if len(qreg) > 1:\n            circuit.h(qreg[-1])\n            circuit.mcx(qreg[:-1], qreg[-1])\n            circuit.h(qreg[-1])\n        else:\n            circuit.z(qreg[0])\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n    return circuit\n'''"}
{"problem": "QPC001_B4", "user": "A5CD8DF1431A5", "submission_order": 2, "result": "RE", "execution_time": "896 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qreg = QuantumRegister(n)\n    circuit = QuantumCircuit(qreg)\n\n\n    most_bit = int(math.log2(L)) + 1\n\n    circuit.x(qreg[most_bit])\n    circuit.z(qreg[most_bit])\n    circuit.x(qreg[most_bit])\n\n\n\n    for i in range(2**(most_bit-1)+1, L):\n        bin_state = format(i, f'0{n}b')[::-1]\n\n        x_gates = [idx for idx, bit in enumerate(bin_state) if bit == '0']\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n        if len(qreg) > 1:\n            circuit.h(qreg[-1])\n            circuit.mcx(qreg[:-1], qreg[-1])\n            circuit.h(qreg[-1])\n        else:\n            circuit.z(qreg[0])\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n    return circuit\n'''"}
{"problem": "QPC001_B4", "user": "A5CD8DF1431A5", "submission_order": 3, "result": "RE", "execution_time": "811 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qreg = QuantumRegister(n)\n    circuit = QuantumCircuit(qreg)\n\n\n    most_bit = int(math.log2(L)) + 1\n\n    circuit.x(qreg[most_bit])\n    circuit.z(qreg[most_bit])\n    circuit.x(qreg[most_bit])\n\n\n\n    for i in range(2**(most_bit-1)+1, L):\n        bin_state = format(i, f'0{n}b')[::-1]\n\n        x_gates = [idx for idx, bit in enumerate(bin_state) if bit == '0']\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n        if len(qreg) > 1:\n            circuit.h(qreg[-1])\n            circuit.mcx(qreg[:-1], qreg[-1])\n            circuit.h(qreg[-1])\n        else:\n            circuit.z(qreg[0])\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n    return circuit\n'''"}
{"problem": "QPC001_B4", "user": "A5CD8DF1431A5", "submission_order": 4, "result": "RE", "execution_time": "997 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit import Aer, execute\n\nimport math\n\n# |x>\\y> -> |x>|y + x>\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qreg = QuantumRegister(n)\n    circuit = QuantumCircuit(qreg)\n\n\n    most_bit = int(math.log2(L)) + 1\n\n    circuit.x(qreg[most_bit])\n    circuit.z(qreg[most_bit])\n    circuit.x(qreg[most_bit])\n\n\n\n    for i in range(2**(most_bit-1)+1, L):\n        bin_state = format(i, f'0{n}b')[::-1]\n\n        x_gates = [idx for idx, bit in enumerate(bin_state) if bit == '0']\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n        if len(qreg) > 1:\n            circuit.h(qreg[-1])\n            circuit.mcx(qreg[:-1], qreg[-1])\n            circuit.h(qreg[-1])\n        else:\n            circuit.z(qreg[0])\n\n        for gate in x_gates:\n            circuit.x(qreg[gate])\n\n    return circuit\n'''"}
{"problem": "QPC001_B4", "user": "A6062DFA54917", "submission_order": 1, "result": "AC", "execution_time": "1731 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    K = L - 1\n\n    xgates = []\n    for i in range(n - 1, -1, -1):\n        if (K >> i) & 1:\n            continue\n\n        if i < n - 1:\n            qc.mcp(pi, list(range(i + 1, n)), i)\n        else:\n            qc.z(i)\n\n        xgates.append(i)\n        qc.x(i)\n\n    for i in xgates:\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6100ACE1E0D1", "submission_order": 1, "result": "RE", "execution_time": "2101 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for k in range(n):\n        qc.h(k)\n    \n    for i in range(L):\n        # Convert index to n-bit binary and little-endian\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]\n\n        # Apply X gates based on binary representation\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n        # Apply the multi-controlled Z gate\n        qc.append(ZGate().control(n - 1), range(n))\n\n        # Reset X gates for the next iteration\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6100ACE1E0D1", "submission_order": 2, "result": "DLE", "execution_time": "1733 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        # Convert index to n-bit binary (big-endian)\n        binary_repr = format(i, f'0{n}b')  \n        little_endian_binary_repr = binary_repr[::-1]  # Convert to little-endian\n\n        # Apply X gates based on binary representation\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n        # Apply multi-controlled Z gate\n        if n == 1:\n            qc.z(0)  # Directly apply Z if there's only one qubit\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n\n        # Reset X gates for the next iteration\n        for j in range(n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6100ACE1E0D1", "submission_order": 3, "result": "AC", "execution_time": "2194 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Get the binary representation of L (with leading zeros)\n    binary_repr = format(L, f'0{n}b')\n    \n    # Step 2: Reverse the binary representation to get little-endian\n    little_endian_binary_repr = binary_repr[::-1]\n\n    # Step 3: Iterate over each qubit (from 0 to n-1)\n    for i in range(n):\n        # Check the value of the i-th bit in the little-endian binary representation of L\n        if little_endian_binary_repr[i] == '0':\n            continue  # Skip if the bit is 0\n\n        # Apply X gates to the qubits for the remaining qubits\n        for j in range(i + 1, n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n        qc.x(i)  # Apply X gate to the current qubit\n\n        # Apply the Z gate or multi-controlled Z gate\n        if i == n - 1:\n            qc.z(i)  # Apply Z to the last qubit\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))  # Apply multi-controlled Z\n\n        qc.x(i)  # Reset the X gate on the current qubit\n\n        # Reset the X gates on the remaining qubits\n        for j in range(i + 1, n):\n            if little_endian_binary_repr[j] == '0':\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6216BE402B6E", "submission_order": 1, "result": "WA", "execution_time": "1055 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    m = L\n    mbin = []\n    k = m\n    tmp = 0\n    while(tmp < n):\n        mbin = mbin + [k%2]\n        k = k //2\n        tmp += 1\n    if mbin[n-1] == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2, -1, -1):\n        bi = mbin[i]\n        if bi == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            lis = [j for j in range(i+1,n)]\n            qc.mcrz(math.pi/2, lis, i)\n            qc.x(i)\n    for i in range(n):\n        if mbin[i] == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6216BE402B6E", "submission_order": 2, "result": "AC", "execution_time": "1375 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    m = L\n    mbin = []\n    k = m\n    tmp = 0\n    while(tmp < n):\n        mbin = mbin + [k%2]\n        k = k //2\n        tmp += 1\n    if mbin[n-1] == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-2, -1, -1):\n        bi = mbin[i]\n        if bi == 0:\n            qc.x(i)\n        else:\n            qc.x(i)\n            lis = [j for j in range(i+1,n)]\n            qc.mcp(math.pi, lis, i)\n            qc.x(i)\n    for i in range(n):\n        if mbin[i] == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A64E234FD7D6A", "submission_order": 1, "result": "DLE", "execution_time": "2106 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not((l>>i) & 1):\n                qc.x(i)\n\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1), range(n))\n        for i in range(n):\n            if not((l>>i)&1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A64E234FD7D6A", "submission_order": 2, "result": "AC", "execution_time": "2290 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    print(b)\n    qc.x(n-1)\n    if b[n-1]:\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in reversed(range(n-1)):\n        qc.x(i)\n        if b[i]:\n            qc.mcp(math.pi, list(range(i+1, n)), i)\n            qc.x(i)\n    for i in range(n):\n        if not b[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A67F40959F57E", "submission_order": 1, "result": "RE", "execution_time": "1059 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    print(b)\n    qc.x(n-1)\n    if b[n-1]:\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in reversed(range(n-1)):\n        qc.x(i)\n        if b[i]:\n            qc.mcp(math.pi, list(range(i+1, n)), i)\n            qc.x(i)\n    for i in range(n):\n        if not b[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A67F40959F57E", "submission_order": 2, "result": "AC", "execution_time": "2666 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    print(b)\n    qc.x(n-1)\n    if b[n-1]:\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in reversed(range(n-1)):\n        qc.x(i)\n        if b[i]:\n            qc.mcp(math.pi, list(range(i+1, n)), i)\n            qc.x(i)\n    for i in range(n):\n        if not b[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A680B1053E1CF", "submission_order": 1, "result": "WA", "execution_time": "1880 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Apply H on all qubits\n    for i in range(n):\n        qc.h(i)\n\n    # Apply Z gate on just one qubit (doesn't matter which)\n    qc.z(0)\n\n    # Apply H again on all qubits\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A680B1053E1CF", "submission_order": 2, "result": "WA", "execution_time": "1963 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    if n == 1:\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A680B1053E1CF", "submission_order": 3, "result": "DLE", "execution_time": "1971 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for l in range(L):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n        if n == 1:\n            qc.z(0)\n        else:\n            # depth 줄이기 위해 ZGate에 mode 지정 (v-chain: ancilla 없이 depth 최소화)\n            mcz = ZGate().control(n - 1, ctrl_state='1' * (n - 1))\n            qc.append(mcz, range(n))\n\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6A94B565FD27", "submission_order": 1, "result": "RE", "execution_time": "916 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        if L==2:\n            qc.z(0)\n        return qc\n\n    for i in reversed(range(n)):\n        print(\"i,L\",i,L)\n        if L>2**i-1:\n            if i==n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.h(i)\n                qc.append(MCXGate(n-i-1, ctrl_state=\"1\"*(n-i-1)), reversed(range(i,n)))\n                qc.h(i)\n                qc.x(i)\n            L-=2**i\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6A94B565FD27", "submission_order": 2, "result": "RE", "execution_time": "872 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        if L==2:\n            qc.z(0)\n        return qc\n\n    for i in reversed(range(n)):\n        if L>2**i-1:\n            if i==n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.h(i)\n                qc.append(MCXGate(n-i-1, ctrl_state=\"1\"*(n-i-1)), reversed(range(i,n)))\n                qc.h(i)\n                qc.x(i)\n            L-=2**i\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6A94B565FD27", "submission_order": 3, "result": "RE", "execution_time": "888 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        if L==2:\n            qc.z(0)\n        return qc\n\n    for i in reversed(range(n)):\n        if L>2**i-1:\n            if i==n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.h(i)\n                qc.append(MCXGate(n-i-1, ctrl_state=\"0\"*(n-i-1)), reversed(range(i,n)))\n                qc.h(i)\n                qc.x(i)\n            L-=2**i\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6E8CD627965F", "submission_order": 1, "result": "RE", "execution_time": "1791 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if not ((l>>j) & 1):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6E8CD627965F", "submission_order": 2, "result": "DLE", "execution_time": "2035 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if not ((l>>i) & 1):\n                qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for j in range(n):\n            if not ((l>>j) & 1):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6FA80F7E20DE", "submission_order": 1, "result": "RE", "execution_time": "1011 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = L\n\n    lst = []\n\n    while (l > 0):\n        if l & 1 == 1:\n            lst.append(1)\n        else:\n            lst.append(0)\n        l = l >> 1\n\n    k = [0 for i in range(n - len(lst))]\n    lst = k + lst\n\n    lst.reverse()\n\n    for i in range(n):\n        if lst[i] == 1:\n            qc.x(n-i-1)\n            if i > 0:\n                qc.append(ZGate().control(n-i-1), range(n-i))\n            else:\n                qc.z(n-i-1)\n            qc.x(n-i-1)\n        else:\n            qc.x(n-i-1)\n\n    for i in range(n):\n        if lst[i] == 0:\n            qc.x(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6FA80F7E20DE", "submission_order": 2, "result": "WA", "execution_time": "1128 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    l = L\n\n    lst = []\n\n    while (l > 0):\n        if l & 1 == 1:\n            lst.append(1)\n        else:\n            lst.append(0)\n        l = l >> 1\n        \n    lst.reverse()\n\n    k = [0 for i in range(n - len(lst))]\n    lst = k + lst\n\n\n    for i in range(len(lst)):\n        if lst[i] == 1:\n            qc.x(n-i-1)\n            if i > 0:\n                qc.append(ZGate().control(i), range(n-i-1,n))\n            else:\n                qc.z(n-i-1)\n            qc.x(n-i-1)\n        else:\n            qc.x(n-i-1)\n\n    for i in range(n):\n        if lst[i] == 0:\n            qc.x(n-i-1)\n            \n    if L == 2**n:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6FA80F7E20DE", "submission_order": 3, "result": "WA", "execution_time": "1191 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    l = L\n\n    lst = []\n\n    if l == 2**(n-1):\n        l = l//2;\n\n    while (l > 0):\n        if l & 1 == 1:\n            lst.append(1)\n        else:\n            lst.append(0)\n        l = l >> 1\n        \n    lst.reverse()\n\n    k = [0 for i in range(n - len(lst))]\n    lst = k + lst\n\n    print(lst)\n\n\n    for i in range(len(lst)):\n        if lst[i] == 1:\n            qc.x(n-i-1)\n            if i > 0:\n                qc.append(ZGate().control(i), range(n-i-1,n))\n            else:\n                qc.z(n-i-1)\n            qc.x(n-i-1)\n        else:\n            qc.x(n-i-1)\n\n    for i in range(len(lst)):\n        if lst[i] == 0:\n            qc.x(n-i-1)\n            \n    if L == 2**n:\n        qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6FA80F7E20DE", "submission_order": 4, "result": "AC", "execution_time": "2535 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    l = L\n\n    lst = []\n\n    if l == 2**n:\n        l = l//2;\n\n    while (l > 0):\n        if l & 1 == 1:\n            lst.append(1)\n        else:\n            lst.append(0)\n        l = l >> 1\n        \n    lst.reverse()\n\n    k = [0 for i in range(n - len(lst))]\n    lst = k + lst\n\n    print(lst)\n\n\n    for i in range(len(lst)):\n        if lst[i] == 1:\n            qc.x(n-i-1)\n            if i > 0:\n                qc.append(ZGate().control(i), range(n-i-1,n))\n            else:\n                qc.z(n-i-1)\n            qc.x(n-i-1)\n        else:\n            qc.x(n-i-1)\n\n    for i in range(len(lst)):\n        if lst[i] == 0:\n            qc.x(n-i-1)\n            \n    if L == 2**n:\n        qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A6FE7498861F9", "submission_order": 1, "result": "WA", "execution_time": "2398 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    for x in range(L):\n        for i in range(n):\n            if not(x >> i & 1):\n                qc.x(i)\n        if n == 1: qc.z(0)\n        else: qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            if not(x >> i & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A7021DD63464C", "submission_order": 1, "result": "DLE", "execution_time": "1408 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if L==1:\n            qc.z(0)\n            \n        return qc\n    # Write your code here:\n    for i in range(L):\n        for j in range(n):\n            if (i//(2**j)) % 2 == 0:\n                qc.x(j)\n        qc.append(ZGate().control(n-1),range(n)) \n        for j in range(n):\n            if (i//(2**j)) % 2== 0:\n                qc.x(j)\n        \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A7021DD63464C", "submission_order": 2, "result": "WA", "execution_time": "902 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if L==1:\n            qc.z(0)\n            \n        return qc\n    # Write your code here:\n    a = L // (2**(n-1))\n    if a == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-1):\n        # print(i)\n        j = n-2 - i\n        b = (L//(2**j))%2\n        if b%2==0:\n            qc.x(j)\n        else:\n            qc.x(j)\n            qc.append(ZGate().control(i+1),reversed(range(n-i-2,n))) \n            qc.x(j)\n    for i in range(n):\n        qc.x(i)\n    # if L==31 and n==5:\n    #     qc.draw(output=\"mpl\",filename=\"img.png\")\n\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC001_B4", "user": "A7021DD63464C", "submission_order": 3, "result": "WA", "execution_time": "1085 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if L==1:\n            qc.z(0)\n            \n        return qc\n    # Write your code here:\n    a = L // (2**(n-1))\n    if a == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-1):\n        # print(i)\n        j = n-2 - i\n        b = (L//(2**j))%2\n        if b%2==0:\n            qc.x(j)\n        else:\n            qc.x(j)\n            qc.append(XGate().control(i+1),reversed(range(n-i-2,n))) \n            qc.x(j)\n    for i in range(n):\n        b = (L//(2**i))%2\n        if b==0:\n            qc.x(i)\n    # if L==11 and n==4:\n    #     qc.draw(output=\"mpl\",filename=\"img.png\")\n\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC001_B4", "user": "A7021DD63464C", "submission_order": 4, "result": "AC", "execution_time": "3000 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if L==1:\n            qc.z(0)\n            \n        return qc\n    # Write your code here:\n    a = L // (2**(n-1))\n    if a == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    for i in range(n-1):\n        # print(i)\n        j = n-2 - i\n        b = (L//(2**j))%2\n        if b%2==0:\n            qc.x(j)\n        else:\n            qc.x(j)\n            qc.append(ZGate().control(i+1),reversed(range(n-i-2,n))) \n            qc.x(j)\n    for i in range(n):\n        b = (L//(2**i))%2\n        if b==0:\n            qc.x(i)\n    # if L==11 and n==4:\n    #     qc.draw(output=\"mpl\",filename=\"img.png\")\n\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC001_B4", "user": "A703C8D585C85", "submission_order": 1, "result": "RE", "execution_time": "1187 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A703C8D585C85", "submission_order": 2, "result": "RE", "execution_time": "746 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = ZGate()\n    qc.append(gate.control(n-1), list(range(n)))\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A72DDE125D9F1", "submission_order": 1, "result": "RE", "execution_time": "835 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif L == 1 << n:\n\t\tqc.append(GlobalPhaseGate(pi))\n\t\treturn qc\n\tcontrolled = []\n\tctrl_state = \"\"\n\tfor bit in range(n, -1, -1):\n\t\tprint(bit)\n\t\tprint(controlled)\n\t\tprint(ctrl_state)\n\t\tif (L >> bit & 1) == 1:\n\t\t\tqc.x(bit)\n\t\t\tif len(controlled) == 0:\n\t\t\t\tqc.z(bit)\n\t\t\telse:\n\t\t\t\tqc.append(ZGate().control(len(controlled), ctrl_state = ctrl_state), controlled + [bit])\n\t\t\tqc.x(bit)\n\treturn qc\n'''"}
{"problem": "QPC001_B4", "user": "A72DDE125D9F1", "submission_order": 2, "result": "RE", "execution_time": "765 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif L == 1 << n:\n\t\tqc.append(GlobalPhaseGate(pi))\n\t\treturn qc\n\tcontrolled = []\n\tctrl_state = \"\"\n\tfor bit in range(n - 1, -1, -1):\n\t\tif (L >> bit & 1) == 1:\n\t\t\tqc.x(bit)\n\t\t\tif len(controlled) == 0:\n\t\t\t\tqc.z(bit)\n\t\t\telse:\n\t\t\t\tqc.append(ZGate().control(len(controlled), ctrl_state = ctrl_state), controlled + [bit])\n\t\t\tqc.x(bit)\n\t\tcontrolled += [bit]\n\t\tctrl_state += chr(ord('0') + (L >> bit & 1))\n\treturn qc\n'''"}
{"problem": "QPC001_B4", "user": "A72DDE125D9F1", "submission_order": 3, "result": "RE", "execution_time": "816 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int)->QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif L == 1 << n:\n\t\tqc.append(GlobalPhaseGate(pi))\n\t\treturn qc\n\tcontrolled = []\n\tctrl_state = \"\"\n\tfor bit in range(n - 1, -1, -1):\n\t\tif (L >> bit & 1) == 1:\n\t\t\tqc.x(bit)\n\t\t\tif len(controlled) == 0:\n\t\t\t\tqc.z(bit)\n\t\t\telse:\n\t\t\t\tqc.append(ZGate().control(len(controlled), ctrl_state = ctrl_state), controlled + [bit])\n\t\t\tqc.x(bit)\n\t\tcontrolled = [bit] + controlled\n\t\tctrl_state += chr(ord('0') + (L >> bit & 1))\n\treturn qc\n'''"}
{"problem": "QPC001_B4", "user": "A72DDE125D9F1", "submission_order": 4, "result": "AC", "execution_time": "1782 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, L: int)->QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif L == 1 << n:\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\tqc.z(0)\n\t\tqc.x(0)\n\t\treturn qc\n\tcontrolled = []\n\tctrl_state = \"\"\n\tfor bit in range(n - 1, -1, -1):\n\t\tif (L >> bit & 1) == 1:\n\t\t\tqc.x(bit)\n\t\t\tif len(controlled) == 0:\n\t\t\t\tqc.z(bit)\n\t\t\telse:\n\t\t\t\tqc.append(ZGate().control(len(controlled), ctrl_state = ctrl_state), controlled + [bit])\n\t\t\tqc.x(bit)\n\t\tcontrolled = [bit] + controlled\n\t\tctrl_state += chr(ord('0') + (L >> bit & 1))\n\treturn qc\n'''"}
{"problem": "QPC001_B4", "user": "A7C3C9A321213", "submission_order": 1, "result": "WA", "execution_time": "2291 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    if n == 1:\n    \tif L == 2:\n    \t\tqc.x(0)\n    \t\tqc.z(0)\n    \t\tqc.x(0)\n    \t\tqc.z(0)\n    \telse:\n    \t\tqc.x(0)\n    \t\tqc.z(0)\n    \t\tqc.x(0)\n    else:\n    \tL -= 1\n\n    \tfor j in range(n):\n    \t\tif (1 << j) & L:\n    \t\t\tqc.x(j)\n    \tqc.append(ZGate().control(n-1), range(n))\n    \tfor j in range(n):\n    \t\tif (1 << j) & L:\n    \t\t\tqc.x(j)\n\n    \tones = []\n    \tfor j in range(n-1, 0, -1):\n    \t\tif (1 << j) & L:\n    \t\t\tqc.x(j)\n\t\t    \tqc.append(ZGate().control(len(ones) + 1), ones + [j] + [0])\n\t\t    \tqc.x(0)\n\t\t    \tqc.append(ZGate().control(len(ones) + 1), ones + [j] + [0])\n\t\t    \tqc.x(0)\n\t\t    \tqc.x(j)\n\n    \t\t\tones.append(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A7C3C9A321213", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\t# for i in range(n):\n\t# \tqc.h(i)\n\t\n\tif n == 1:\n\t\tif L == 2:\n\t\t\tqc.x(0)\n\t\t\tqc.z(0)\n\t\t\tqc.x(0)\n\t\t\tqc.z(0)\n\t\telse:\n\t\t\tqc.x(0)\n\t\t\tqc.z(0)\n\t\t\tqc.x(0)\n\telse:\n\t\tL -= 1\n\n\t\tfor j in range(n):\n\t\t\tif not ((1 << j) & L):\n\t\t\t\tqc.x(j)\n\t\tqc.append(ZGate().control(n-1), range(n))\n\t\tfor j in range(n):\n\t\t\tif not ((1 << j) & L):\n\t\t\t\tqc.x(j)\n\n\t\tl=L\n\n\t\tones = []\n\t\tfor j in range(n-1, -1, -1):\n\t\t\tif (1 << j) & L:\n\t\t\t\tl -= 1 << j\n\t\t\t\tif (n-j-1 > 0):\n\t\t\t\t\tfor i in range(n-1, j-1, -1):\n\t\t\t\t\t\tif i not in ones:\n\t\t\t\t\t\t\tqc.x(i)\n\n\t\t\t\t\tqc.append(ZGate().control(n-j-1), list(range(n-1, j-1, -1)))\n\n\t\t\t\t\tfor i in range(n-1, j-1, -1):\n\t\t\t\t\t\tif i not in ones:\n\t\t\t\t\t\t\tqc.x(i)\n\n\t\t\t\t\tones.append(j)\n\t\t\t\telse:\n\t\t\t\t\tqc.x(j)\n\t\t\t\t\tqc.z(j)\n\t\t\t\t\tqc.x(j)\n\t\t\t\t\tones.append(j)\n\treturn qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 1, "result": "RE", "execution_time": "1382 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        for j in range(n):\n            if (1 << j) & i == 0:\n                qc.x(j)\n\n        if n > 1:\n            qc.append(ZGate().control(n - 1), range(n))\n        else:\n            qc.z(0)\n\n        for j in range(n):\n            if (1 << j) & i == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 2, "result": "DLE", "execution_time": "2213 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        for j in range(n):\n            if (1 << j) & i == 0:\n                qc.x(j)\n\n        if n > 1:\n            qc.append(ZGate().control(n - 1), range(n))\n        else:\n            qc.z(0)\n\n        for j in range(n):\n            if (1 << j) & i == 0:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 3, "result": "RE", "execution_time": "1285 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        binary_str = format(i, f'0{n}b')\n\n        if n > 1:\n            qc.append(ZGate().control(n - 1, ctrl_state=binary_str), range(n))\n        else:\n            qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 4, "result": "RE", "execution_time": "1292 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        binary_str = format(i, f'0{n-1}b')\n\n        if n > 1:\n            qc.append(ZGate().control(n - 1, ctrl_state=binary_str), range(n))\n        else:\n            qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 5, "result": "RE", "execution_time": "2009 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        binary_str = format(i, f'0{n-1}b')\n\n        if n > 1:\n            qc.append(ZGate().control(n - 1, ctrl_state=binary_str), range(n))\n        else:\n            qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 6, "result": "RE", "execution_time": "1590 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        #binary_str = format(i, f'0{n-1}b')\n        binary_str = f'{i:0{n-1}b}'\n\n        if n > 1:\n            qc.append(ZGate().control(n - 1, ctrl_state=binary_str), range(n))\n        else:\n            qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 7, "result": "WA", "execution_time": "1832 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        binary_str = f'{i:0{n}b}'[::-1]\n        \n        if n > 1:\n          if binary_str[0] == '0':\n            qc.x(n - 1)\n          qc.append(ZGate().control(n - 1, ctrl_state=binary_str[1:]), range(n))\n          if binary_str[0] == '0':\n            qc.x(n - 1)\n        else:\n            qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(L):\n\n        for i in range(n - 1, -1, -1):\n        if (((L - 1) >> i) & 1):\n            qc.x(i)\n            if i == n - 1:\n                qc.z(i)\n            else:\n                controls = list(range(i + 1, n))\n                cz_gate = ZGate().control(len(controls))\n                qc.append(cz_gate, controls + [i])\n            qc.x(i)\n        else:\n            qc.x(i)\n\n    if n > 1:\n        controls = list(range(1, n))\n        cz_gate = ZGate().control(len(controls))\n        qc.append(cz_gate, controls + [0])\n    else:\n        qc.z(0)\n\n    for i in range(n - 1, -1, -1):\n        if not (((L - 1) >> i) & 1):\n            qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A86A158F3DC7F", "submission_order": 9, "result": "AC", "execution_time": "2845 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        if (((L - 1) >> i) & 1):\n            qc.x(i)\n            if i == n - 1:\n                qc.z(i)\n            else:\n                controls = list(range(i + 1, n))\n                cz_gate = ZGate().control(len(controls))\n                qc.append(cz_gate, controls + [i])\n            qc.x(i)\n        else:\n            qc.x(i)\n\n    if n > 1:\n        controls = list(range(1, n))\n        cz_gate = ZGate().control(len(controls))\n        qc.append(cz_gate, controls + [0])\n    else:\n        qc.z(0)\n\n    for i in range(n - 1, -1, -1):\n        if not (((L - 1) >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A8A04EF919EBB", "submission_order": 1, "result": "AC", "execution_time": "2654 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 2**n:\n      qc.rx(2*math.pi,0)\n    else:\n      L_code = format(L, f'0{n}b')\n      for i in range(n):\n          if L_code[i] == \"1\":\n              for j in range(i):\n                  if L_code[j] == \"0\":\n                      qc.x(n-j-1)\n              qc.x(n-i-1)\n              if i == 0:\n                  qc.z(n-1)\n              else:\n                  qc.append(ZGate().control(i), qargs=range(n-1,n-i-2,-1))\n              for j in range(i):\n                  if L_code[j] == \"0\":\n                      qc.x(n-j-1)\n              qc.x(n-i-1)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A8BA6F879A2F1", "submission_order": 1, "result": "AC", "execution_time": "1386 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve_rec(qc: QuantumCircuit, n: int, bit: int, L: int) -> None:\n    if bit < 0:\n        return\n    if L < (1<<bit):\n        qc.x(bit)\n        solve_rec(qc, n, bit-1, L)\n        qc.x(bit)\n    else:\n        qc.x(bit)\n        qc.mcp(math.pi, list(range(bit+1,n)), bit)\n        qc.x(bit)\n        solve_rec(qc, n, bit-1, L-(1<<bit))\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1 and L == 1:\n        qc.p(math.pi, 0)\n    if n == 1:\n        return qc\n    if L < (1<<(n-1)):\n        qc.x(n-1)\n        solve_rec(qc, n, n-2, L)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n        solve_rec(qc, n, n-2, L-(1<<(n-1)))\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A8E863A7CE002", "submission_order": 1, "result": "RE", "execution_time": "1044 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A8E863A7CE002", "submission_order": 2, "result": "RE", "execution_time": "727 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n                \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A91600CD0EE7C", "submission_order": 1, "result": "AC", "execution_time": "2604 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A91FDEBA196D6", "submission_order": 1, "result": "WA", "execution_time": "1002 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L -= 1\n\n    # 消す！！！\n    for i in range(n):\n        qc.h(i)\n\n    # Write your code here:\n    if n == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n    else:\n        L_keta = 1\n        for i in range(n):\n            if 2**i <= L:\n                L_keta = i+1\n\n        for i in range(L_keta-1):\n            qc.x(n-i-1)\n\n        # 最初の000の部分を除く\n        # MCZ start\n        qc.h(n - 1)\n        if n - L_keta > 1:\n            qc.mcx(list(range(L_keta, n-1)), n - 1)\n        else:\n            qc.x(n - 1)\n        qc.h(n - 1)\n        # MCZ end\n        for i in range(L_keta-1):\n            qc.x(n-i-1)\n\n        zero_bit_idx = set(list(range(n-1, L_keta-1, -1)))\n        for j in range(L_keta-2, -1, -1):  # このループが一番のポイント\n            if ((L >> j) & 1)==0:  # 順に右にシフトさせ最下位bitのチェックを行う\n                # フラグが立っていたら mcz\n\n                for i in range(n):\n                    if i in zero_bit_idx:\n                        qc.x(i)\n                # MCZ start\n                qc.h(n - 1)\n                qc.mcx(list(range(j, n-1)), n - 1)\n                qc.h(n - 1)\n                # MCZ end\n                for i in range(n):\n                    if i in zero_bit_idx:\n                        qc.x(i)\n                zero_bit_idx.add(j)\n\n\n    return qc\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A9214B04F2DB3", "submission_order": 1, "result": "WA", "execution_time": "1119 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    flip = []\n    for i in range(n):\n        if L >= 2**(n-1-i):\n            qc.x(n-1-i)\n            if i != 0:\n                qc.append(ZGate().control(i), [n-1-_ for _ in range(i + 1)])\n            else:\n                qc.z(n-1)\n            qc.x(n-1-i)\n        else:\n            qc.x(n-1-i)\n            flip.append(n-1-i)\n        L %= 2**(n-1-i)\n    for f in flip:\n        qc.x(f)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A9214B04F2DB3", "submission_order": 2, "result": "AC", "execution_time": "2248 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 2**n:\n        pass\n    else:\n        flip = []\n        for i in range(n):\n            if L >= 2**(n-1-i):\n                qc.x(n-1-i)\n                if i != 0:\n                    qc.append(ZGate().control(i), [n-1-_ for _ in range(i + 1)])\n                else:\n                    qc.z(n-1)\n                qc.x(n-1-i)\n            else:\n                qc.x(n-1-i)\n                flip.append(n-1-i)\n            L %= 2**(n-1-i)\n        for f in flip:\n            qc.x(f)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A925F37B0B029", "submission_order": 1, "result": "AC", "execution_time": "1780 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.initialize([0.5,0.5,0.5,0.5])\n\n    # Write your code here:\n    v = 0\n    for i in range(n-1, -1, -1):\n        if (L>>i)&1:\n            for j in range(n-1, i-1, -1):\n                if ((v>>j)&1)==0:\n                    qc.x(j)\n            if i==n-1:\n                qc.z(i)\n            else:\n                qc.h(i)\n                qc.mcx(list(range(i+1, n)), i)\n                qc.h(i)\n            for j in range(n-1, i-1, -1):\n                if ((v>>j)&1)==0:\n                    qc.x(j)\n            v ^= (1<<i)\n    # print(qc.depth())\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(10, 1023)\n    # print(Statevector(qc))\n'''"}
{"problem": "QPC001_B4", "user": "A96E0F01693FE", "submission_order": 1, "result": "WA", "execution_time": "2287 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & (1 << i) == 0:\n            continue\n        for _j in range(i + 1,n):\n            if L & (1 << i) == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for _j in range(i + 1,n):\n            if L & (1 << i) == 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A96E0F01693FE", "submission_order": 2, "result": "RE", "execution_time": "1487 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & (1 << i) == 0:\n            continue\n        for _j in range(i + 1,n):\n            if L & (1 << _j) == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for _j in range(i + 1,n):\n            if L & (1 << _j) == 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A96E0F01693FE", "submission_order": 3, "result": "AC", "execution_time": "1960 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & (1 << i) == 0:\n            continue\n        for j in range(i + 1,n):\n            if L & (1 << j) == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1,n):\n            if L & (1 << j) == 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A999F447350E9", "submission_order": 1, "result": "AC", "execution_time": "2243 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    # Write your code here:\n    if L == (1<<n):\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n        qc.z(n-1)\n        return qc\n    tmp = 0\n    tmp_flip = []\n    for i in reversed(range(n)):\n        # print(tmp)\n        # print(1<<i)\n        if tmp+(1<<i) <= L:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                for y in tmp_flip:\n                    qc.x(y)\n                qc.x(i)\n                qc.h(i)\n                qc.mcx(list(range(i+1,n)),i)\n                qc.h(i)\n                qc.x(i)\n                for y in tmp_flip:\n                    qc.x(y)\n            tmp += (1<<i)\n        else:\n            tmp_flip.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A99CC1391BE12", "submission_order": 1, "result": "RE", "execution_time": "836 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    Lbit = format(L, f'0{n}b')\n    #print(Lbit)\n    xcx_list = []    \n    for i in range(n):\n        if Lbit[i]=='1':\n            if i==0:\n                qc.z(n-1)\n            else:\n                for j in xcx_list:\n                    qc.x(j)\n                gate_x = XGate().control(i)\n                gate_z = ZGate().control(i)\n                ctrl_qubits = list(range(n-i, n))  # 制御ビットの範囲\n                target_qubit = [n-i-1]\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                qc.append(gate_z, ctrl_qubits + target_qubit)\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                #print(ctrl_qubits)\n                #print(target_qubit)\n                for j in xcx_list:\n                    qc.x(j)\n        else:\n            xcx_list.append(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A99CC1391BE12", "submission_order": 2, "result": "WA", "execution_time": "875 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    Lbit = format(L, f'0{n}b')\n    #print(Lbit)\n    xcx_list = []    \n    for i in range(n):\n        if Lbit[i]=='1':\n            if i==0:\n                qc.z(n-1)\n            else:\n                for j in xcx_list:\n                    qc.x(j)\n                gate_x = XGate().control(i)\n                gate_z = ZGate().control(i)\n                ctrl_qubits = list(range(n-i, n))  # 制御ビットの範囲\n                target_qubit = [n-i-1]\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                qc.append(gate_z, ctrl_qubits + target_qubit)\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                #print(ctrl_qubits)\n                #print(target_qubit)\n                for j in xcx_list:\n                    qc.x(j)\n        else:\n            xcx_list.append(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A99CC1391BE12", "submission_order": 3, "result": "WA", "execution_time": "1281 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    Lbit = format(L, f'0{n}b')\n    #print(Lbit)\n    xcx_list = []    \n    for i in range(n):\n        if Lbit[i]=='1':\n            if i==0:\n                qc.z(n-1)\n            else:\n                for j in xcx_list:\n                    qc.x(j)\n                gate_x = XGate().control(i)\n                gate_z = ZGate().control(i)\n                ctrl_qubits = list(range(n-i, n))  # 制御ビットの範囲\n                target_qubit = [n-i-1]\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                qc.append(gate_z, ctrl_qubits + target_qubit)\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                #print(ctrl_qubits)\n                #print(target_qubit)\n                for j in xcx_list:\n                    qc.x(j)\n        else:\n            xcx_list.append(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A99CC1391BE12", "submission_order": 4, "result": "WA", "execution_time": "923 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    Lbit = format(L, f'0{n}b')\n    #print(Lbit)\n    xcx_list = []    \n    for i in range(n):\n        if Lbit[i]=='1':\n            if i==0:\n                qc.x(n-1)\n                qc.z(n-1)\n                qc.x(n-1)\n            else:\n                for j in xcx_list:\n                    qc.x(j)\n                gate_x = XGate().control(i)\n                gate_z = ZGate().control(i)\n                ctrl_qubits = list(range(n-i, n))  # 制御ビットの範囲\n                target_qubit = [n-i-1]\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                qc.append(gate_z, ctrl_qubits + target_qubit)\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                #print(ctrl_qubits)\n                #print(target_qubit)\n                for j in xcx_list:\n                    qc.x(j)\n        else:\n            xcx_list.append(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A99CC1391BE12", "submission_order": 5, "result": "WA", "execution_time": "874 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    Lbit = format(L, f'0{n}b')\n    #print(Lbit)\n    xcx_list = []    \n    for i in range(n):\n        if Lbit[i]=='1':\n            if i==0:\n                qc.x(n-1)\n                qc.z(n-1)\n                qc.x(n-1)\n            else:\n                for j in xcx_list:\n                    qc.x(j)\n                gate_x = XGate().control(i)\n                gate_z = ZGate().control(i)\n                ctrl_qubits = list(range(n-i, n))  # 制御ビットの範囲\n                target_qubit = [n-i-1]\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                qc.append(gate_z, ctrl_qubits + target_qubit)\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                #print(ctrl_qubits)\n                #print(target_qubit)\n                for j in xcx_list:\n                    qc.x(j)\n        else:\n            xcx_list.append(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A99CC1391BE12", "submission_order": 6, "result": "AC", "execution_time": "1199 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==2**n:\n        return qc\n    Lbit = format(L, f'0{n}b')\n    #print(Lbit)\n    xcx_list = []    \n    for i in range(n):\n        if Lbit[i]=='1':\n            if i==0:\n                qc.x(n-1)\n                qc.z(n-1)\n                qc.x(n-1)\n            else:\n                for j in xcx_list:\n                    qc.x(j)\n                gate_x = XGate().control(i)\n                gate_z = ZGate().control(i)\n                ctrl_qubits = list(range(n-i, n))  # 制御ビットの範囲\n                target_qubit = [n-i-1]\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                qc.append(gate_z, ctrl_qubits + target_qubit)\n                qc.append(gate_x, ctrl_qubits + target_qubit)\n                #print(ctrl_qubits)\n                #print(target_qubit)\n                for j in xcx_list:\n                    qc.x(j)\n        else:\n            xcx_list.append(n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A9CC9154637DF", "submission_order": 1, "result": "RE", "execution_time": "2008 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n    else:\n        if (L>>(n-1)) == 0:\n            qc.x(n-1)\n        else:\n            qc.x(n-1)\n            qc.z(n-1)\n            qc.x(n-1)\n        for i in range(n-2,-1,-1):\n            if (L>>i) == 0:\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.apend(ZGate().control(n-i),range(n-1,-1,i-1))\n                qc.x(i)\n        for i in range(n):\n            if (L>>i) == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A9CC9154637DF", "submission_order": 2, "result": "WA", "execution_time": "1710 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n    else:\n        if (L>>(n-1)) == 0:\n            qc.x(n-1)\n        else:\n            qc.x(n-1)\n            qc.z(n-1)\n            qc.x(n-1)\n        for i in range(n-2,-1,-1):\n            if (L>>i) == 0:\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n-i-1),range(n-1,i-1,-1))\n                qc.x(i)\n        for i in range(n):\n            if (L>>i) == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A9CC9154637DF", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n    else:\n        if (L>>(n-1))&1 == 0:from qiskit.circuit.library import ZGate\n            qc.x(n-1)\n        else:\n            qc.x(n-1)\n            qc.z(n-1)\n            qc.x(n-1)\n        for i in range(n-2,-1,-1):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n-i-1),range(n-1,i-1,-1))\n                qc.x(i)\n        for i in range(n):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "A9CC9154637DF", "submission_order": 4, "result": "AC", "execution_time": "2165 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n    else:\n        if (L>>(n-1))&1 == 0:\n            qc.x(n-1)\n        else:\n            qc.x(n-1)\n            qc.z(n-1)\n            qc.x(n-1)\n        for i in range(n-2,-1,-1):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n-i-1),range(n-1,i-1,-1))\n                qc.x(i)\n        for i in range(n):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AA15EBFA68F66", "submission_order": 1, "result": "RE", "execution_time": "2210 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not((L >> i) & 1):\n            continue\n            \n        for j in range(i + 1, n):\n            if not((L >> j) & 1):\n                qc.x(j)\n\n        qc.x(i)\n        qc.append(ZGate().control(n - i - 1), range(i, n)) \n\n        for j in range(i + 1, n):\n            if not((L >> j) & 1):\n                qc.x(j)\n\n        qc.x(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AA15EBFA68F66", "submission_order": 2, "result": "AC", "execution_time": "2313 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not((L >> i) & 1):\n            continue\n            \n        for j in range(i + 1, n):\n            if not((L >> j) & 1):\n                qc.x(j)\n\n        qc.x(i)\n\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n)) \n\n        for j in range(i + 1, n):\n            if not((L >> j) & 1):\n                qc.x(j)\n\n        qc.x(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AA783BF434AFC", "submission_order": 1, "result": "AC", "execution_time": "2212 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n \ndef add_rule(qc: QuantumCircuit, n: int, suffix: list[int]) -> None:\n    idx = n - 1\n    for bit in suffix:\n        if bit == 0:\n            qc.x(idx)\n        idx -= 1\n\n    k = len(suffix)\n    bits = list(reversed(range(n - 1, n - k - 1, -1))) + [n]\n    qc.append(XGate().control(k), bits)\n\n    idx = n - 1\n    for bit in suffix:\n        if bit == 0:\n            qc.x(idx)\n        idx -= 1\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    minus = QuantumRegister(1)\n    qc.add_bits(minus)\n\n    qc.x(n)\n    qc.h(n)\n\n    suffix = []\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            add_rule(qc, n, suffix + [0])\n            suffix.append(1)\n        else:\n            suffix.append(0)\n\n    qc.h(n)\n    qc.x(n)\n\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AA8D9A990D686", "submission_order": 1, "result": "RE", "execution_time": "882 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h([i])\n    qc.x([i])\n    qc.h([i])\n    qc.z([i])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AA8D9A990D686", "submission_order": 2, "result": "WA", "execution_time": "966 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # オラクルの実装\n    for i in range(L):\n        qc.z([i % n])  # 各状態に対してZゲートを適用\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AA8D9A990D686", "submission_order": 3, "result": "RE", "execution_time": "781 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # オラクルの実装\n    for i in range(L):\n        qc.z([i /n])  # 各状態に対してZゲートを適用\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AAE290CF256E1", "submission_order": 1, "result": "AC", "execution_time": "2997 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\nimport math\n\n\ndef add_negative_gate(\n    qc: QuantumCircuit, n: int, zero_indices: list[int], t: QuantumRegister, base: int\n):\n    if len(zero_indices) > 0:\n        qc.x(zero_indices)\n    qc.append(XGate().control(n - base), [*range(base, n), t])\n    qc.crx(math.pi * 2.0, t, 0)\n    # Restore the state of t\n    qc.append(XGate().control(n - base), [*range(base, n), t])\n    if len(zero_indices) > 0:\n        qc.x(zero_indices)\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # FOR TEST\n    # qc.h(range(n))\n\n    t = QuantumRegister(1, \"t\")\n    qc.add_bits(t)\n\n    bits = [((L - 1) >> j) & 1 for j in range(n)]\n    # print(bits)\n\n    for i in reversed(range(n)):\n        if bits[i] == 1:\n            # print(f\"Creat negative gate {list([0] + bits[i+1:])} from {i} bit\")\n\n            # Apply gates based on bits\n            zero_indices = [\n                j + i for j, bit in enumerate([0] + bits[i + 1 :]) if bit == 0\n            ]\n            if len(zero_indices) > 0:\n                qc.x(zero_indices)\n            qc.append(XGate().control(n - i), [*range(i, n), t])\n            qc.crx(math.pi * 2.0, t, 0)\n            # Restore the state of t\n            qc.append(XGate().control(n - i), [*range(i, n), t])\n            if len(zero_indices) > 0:\n                qc.x(zero_indices)\n\n    # Add gate for L-1\n    zero_indices = [j for j, bit in enumerate(bits) if bit == 0]\n    add_negative_gate(qc, n, zero_indices, t, 0)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB12CADCF8599", "submission_order": 1, "result": "RE", "execution_time": "880 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    l_tmp = 1 << n\n    x_lst = []\n    for _i in range(n)[::-1]:\n        if(l_tmp - (1 << _i) >= L):\n            for j in x_lst: qc.x(j)\n\n            if _i == n - 1:\n                qc.z(n - 1)\n            else:\n                qc.append(ZGate().control(n - 1 - _i), list(range(_i, n)))\n            \n            for j in x_lst: qc.x(j)\n            l_tmp -= (1 << _i)\n            \n            x_lst.append(_i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB12CADCF8599", "submission_order": 2, "result": "AC", "execution_time": "2091 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l_tmp = 1 << n\n    x_lst = []\n    for _i in range(n)[::-1]:\n        if(l_tmp - (1 << _i) >= L):\n            for j in x_lst: qc.x(j)\n\n            if _i == n - 1:\n                qc.z(n - 1)\n            else:\n                qc.append(ZGate().control(n - 1 - _i), list(range(_i, n)))\n            \n            for j in x_lst: qc.x(j)\n            l_tmp -= (1 << _i)\n            \n            x_lst.append(_i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB20FAECBEA6B", "submission_order": 1, "result": "AC", "execution_time": "2430 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (L & (1 << i)) == 0:\n            qc.x(i)\n    for i in range(n):\n        if (L & (1 << i)) != 0:\n            qc.x(i)\n            if i + 1 < n:\n                qc.append(ZGate().control(n - i - 1), range(i, n))\n            else:\n                qc.z(i)\n            qc.x(i)\n    for i in range(n):\n        if (L & (1 << i)) == 0:\n            qc.x(i)\n    # print(qc)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n\n#     qc = solve(3, 5)\n#     print(Statevector(qc))\n#     sv = Statevector.from_label('+++')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC001_B4", "user": "AB3586F3B286D", "submission_order": 1, "result": "RE", "execution_time": "922 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB3586F3B286D", "submission_order": 2, "result": "AC", "execution_time": "1560 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n\n    if (L == 2 ** n):\n        return qc\n\n    ll = []\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB41B56A22514", "submission_order": 1, "result": "RE", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i & 1):\n            qc.x(i)\n            for k in range(i+1, n):\n                if not (L>>k & 1):\n                    qc.x(k)\n            if n==1:\n                qc.z(0)\n            else:\n                qc.append(ZGate().control(n-1), range(n))\n            qc.x(i)\n            for k in range(i+1, n):\n                if not (L>>k & 1):\n                    qc.x(k)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB41B56A22514", "submission_order": 2, "result": "WA", "execution_time": "1444 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i & 1):\n            qc.x(i)\n            for k in range(i+1, n):\n                if not (L>>k & 1):\n                    qc.x(k)\n            if n==1:\n                qc.z(0)\n            else:\n                qc.append(ZGate().control(n-1), range(n))\n            qc.x(i)\n            for k in range(i+1, n):\n                if not (L>>k & 1):\n                    qc.x(k)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB41B56A22514", "submission_order": 3, "result": "AC", "execution_time": "2850 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i & 1):\n            qc.x(i)\n            for k in range(i+1, n):\n                if not (L>>k & 1):\n                    qc.x(k)\n            if i == n - 1:\n                qc.z(i)\n            else:\n                qc.append(ZGate().control(n - i - 1), range(i, n))\n            qc.x(i)\n            for k in range(i+1, n):\n                if not (L>>k & 1):\n                    qc.x(k)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB4A32F71999D", "submission_order": 1, "result": "DLE", "execution_time": "989 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 1:\n            qc.p(math.pi, 0)\n    else:\n        for j in range((1 << n) - L):\n            for i in range(n):\n                if((j >> i) & 1):\n                    qc.x(i)\n            qc.mcp(math.pi, qc.qregs[0][:n-1], qc.qregs[0][n-1])\n            for i in range(n):\n                if((j >> i) & 1):\n                    qc.x(i)\n        \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB4A32F71999D", "submission_order": 2, "result": "WA", "execution_time": "1011 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 1:\n            qc.p(math.pi, 0)\n    else:\n        v = []\n        for j in range(n - 1, -1, -1):\n            if (L >> j) & 1:\n                v.append(1)\n            else:\n                x = (n - 1) - j\n                if x == 0:\n                    qc.p(math.pi, j)\n                else:\n                    for k in range(j + 1, n):\n                        if v[(n - 1) - k] == 0:\n                            qc.h(k)\n                    qc.mcp(math.pi, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                    for k in range(j + 1, n):\n                        if v[(n - 1) - k] == 0:\n                            qc.h(k)\n                \n                v.append(0)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB527C4E74F97", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n): # remove when submit\n    qc.h(i)\n\n    for i in range(n):\n    if (L >> i) & 1 == 0: # l_i is 0; condition for (m_i < l_i)\n        continue\n    else: # l_i = 1 & m_i = 0 ; l_i = m_i = 1 case is eliminated at previous step\n        for j in range(i+1, n):\n        if (L >> j) & 1 == 0:\n            qc.x(j)\n        \n        qc.x(i)\n\n        if (i == n - 1):\n        qc.z(i)\n        else:\n        qc.append(ZGate().control(n - i - 1), range(i, n))\n        \n        qc.x(i)\n\n        for j in range(i+1, n):\n        if (L >> j) & 1 == 0:\n            qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB527C4E74F97", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if (L >> i) & 1 == 0: # l_i is 0; condition for (m_i < l_i)\n            continue\n        else: # l_i = 1 & m_i = 0 ; l_i = m_i = 1 case is eliminated at previous step\n            for j in range(i+1, n):\n                if (L >> j) & 1 == 0:\n                    qc.x(j)\n                \n            qc.x(i)\n\n            if (i == n - 1):\n                qc.z(i)\n            else:\n                qc.append(ZGate().control(n - i - 1), range(i, n))\n            \n            qc.x(i)\n\n            for j in range(i+1, n):\n                if (L >> j) & 1 == 0:\n                    qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB56CC174D6B3", "submission_order": 1, "result": "AC", "execution_time": "2424 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if ~L >> i & 1: continue\n        qc.x(i)\n        for j in range(i + 1, n):\n            if L >> j & 1: continue\n            qc.x(j)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        for j in range(i + 1, n):\n            if L >> j & 1: continue\n            qc.x(j)\n        qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AB6E034199FF5", "submission_order": 1, "result": "WA", "execution_time": "894 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ceil, log2\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # エンコードする必要がある状態の数\n    num_bits = ceil(log2(L))\n    \n    # L までの全ての状態に対して、エンコードされたビット位置のビット数だけで条件付きXゲート(CNOT)を適用\n    for i in range(num_bits):\n        if not (L >> i) & 1:  # iビット目が0ならば、そのビットに対してXゲートを適用\n            qc.x(i)\n    \n    # multi-controlled Zゲートを適用することで、必要な状態に-1の位相を追加\n    if num_bits > 1:\n        qc.h(num_bits-1)\n        qc.mct(list(range(num_bits-1)), num_bits-1)  # multi-controlled-toffoli\n        qc.h(num_bits-1)\n    else:\n        qc.z(0)\n\n    # ビットをもとに戻す\n    for i in range(num_bits):\n        if not (L >> i) & 1:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 1, "result": "DLE", "execution_time": "1391 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 2, "result": "DLE", "execution_time": "1825 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 > 2 ** n:\n        solve(n, 2 ** n - L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 3, "result": "WA", "execution_time": "961 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if n == 5:\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 4, "result": "WA", "execution_time": "1017 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 1:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 1:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, 2 ** n - L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n\nif __name__ == \"__main__\":\n    c = solve(2, 3)\n    print(c)\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 5, "result": "WA", "execution_time": "1065 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 1:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 1:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, 2 ** n - L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 6, "result": "WA", "execution_time": "1120 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 1:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 1:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 7, "result": "DLE", "execution_time": "1670 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 8, "result": "DLE", "execution_time": "1458 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 >= 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 9, "result": "DLE", "execution_time": "1435 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n\nif __name__ == \"__main__\":\n    c = solve(3, 7)\n    print(c)\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 10, "result": "WA", "execution_time": "1188 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L == 16 and n == 5:\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n\nif __name__ == \"__main__\":\n    c = solve(3, 7)\n    print(c)\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 11, "result": "WA", "execution_time": "1008 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 == 2 ** n:\n        qc.z(0)\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n\nif __name__ == \"__main__\":\n    c = solve(2, 2)\n    print(c)\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 12, "result": "DLE", "execution_time": "1431 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 == 2 ** n:\n        # qc.z(0)\n        # return qc\n        pass\n\n    if L * 2 > 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n\nif __name__ == \"__main__\":\n    c = solve(2, 2)\n    print(c)\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 13, "result": "DLE", "execution_time": "1472 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 == 2 ** n:\n        qc.z(n - 1)\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n\nif __name__ == \"__main__\":\n    c = solve(2, 2)\n    print(c)\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 14, "result": "DLE", "execution_time": "1433 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve2(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    qr = qc.qregs[0]\n    for i in range(L, 2 ** n):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 == 2 ** n:\n        qc.z(n - 1)\n        return qc\n\n    if L * 2 > 2 ** n:\n        return solve2(n, L)\n\n    qr = qc.qregs[0]\n    for i in range(L):\n        gate = ZGate()\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n        qc.append(ZGate().control(n - 1), qr)\n        for j in range(n):\n            if i & (1 << j) == 0:\n                qc.x(qr[j])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 15, "result": "RE", "execution_time": "830 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 <= 2 ** n:\n        smaller_circuit = solve(n - 1, L).control(1)\n\n        qc.x(n - 1)\n        qc.append(smaller_circuit, [qc.qubits[n - 1]] + qc.qubits[0:n-1])\n        qc.x(n - 1)\n    else:\n        qc.x(n - 1)\n        qc.z(n - 1)\n        qc.x(n - 1)\n        smaller_circuit = solve(n - 1, L - 2 ** (n - 1)).control(1)\n        qc.append(smaller_circuit, [qc.qubits[n - 1]] + qc.qubits[0:n-1])\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABB063C04878F", "submission_order": 16, "result": "WA", "execution_time": "1120 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.z(0)\n        else:\n            assert L == 2\n        return qc\n\n    if L * 2 <= 2 ** n:\n        smaller_circuit = solve(n - 1, L).control(1)\n\n        qc.x(n - 1)\n        qc.append(smaller_circuit, [qc.qubits[n - 1]] + qc.qubits[0:n-1])\n        qc.x(n - 1)\n    else:\n        qc.x(n - 1)\n        qc.z(n - 1)\n        qc.x(n - 1)\n        smaller_circuit = solve(n - 1, L - 2 ** (n - 1)).control(1)\n        qc.append(smaller_circuit, [qc.qubits[n - 1]] + qc.qubits[0:n-1])\n\n    return qc.decompose()\n'''"}
{"problem": "QPC001_B4", "user": "ABB5844230C5E", "submission_order": 1, "result": "DLE", "execution_time": "1754 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    global v\n    v=2**n-1\n    # Write your code here:\n    def f():\n        if n==1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    def g(n):\n        qc.x(n)\n    def h(n):\n        global v\n        if n>0:\n            h(n-1)\n        g(n)\n        v^=2**n\n        if v<L:\n            f()\n        if n>0:\n            h(n-1)\n    h(n-1)\n    g(n-1)\n\n    if 2**n==L:\n        f()\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABD081A7B5C96", "submission_order": 1, "result": "DLE", "execution_time": "1953 ms", "memory": "97 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    is_flip = [0] * (2**n)\n\n    for i in range(L, 2**n):\n        if is_flip[i]:\n            continue\n        bits = []\n        q = i\n        pos = 0\n        while q > 0:\n            if q % 2:\n                bits.append(pos)\n            pos += 1\n            q >>= 1\n        for j in range(i, 2**n):\n            if (i & j) == i:\n                is_flip[j] ^= 1\n\n        if len(bits) == 1:\n            qc.z(bits[0])\n        else:\n            qc.append(ZGate().control(len(bits) - 1), bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABD081A7B5C96", "submission_order": 2, "result": "RE", "execution_time": "1004 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef recursive(qc, L, l, r, ppos, npos, pos):\n    if r <= L:\n        return\n    elif L <= l:\n        for i in npos:\n            qc.x(i)\n        bits = ppos + npos\n        if len(bits) == 1:\n            qc.z(bits[0])\n        else:\n            qc.append(ZGate().control(len(bits) - 1), bits)\n\n        for i in npos:\n            qc.x(i)\n        depth += 3\n    else:\n        mid = (l + r) // 2\n        recursive(qc, L, l, mid, ppos, npos + [pos], pos - 1)\n        recursive(qc, L, mid, r, ppos + [pos], npos, pos - 1)\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    recursive(qc, L, 0, 2**n, [], [], n - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABD081A7B5C96", "submission_order": 3, "result": "AC", "execution_time": "1258 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef recursive(qc, L, l, r, ppos, npos, pos):\n    if r <= L:\n        return\n    elif L <= l:\n        for i in npos:\n            qc.x(i)\n        bits = ppos + npos\n        if len(bits) == 1:\n            qc.z(bits[0])\n        else:\n            qc.append(ZGate().control(len(bits) - 1), bits)\n\n        for i in npos:\n            qc.x(i)\n    else:\n        mid = (l + r) // 2\n        recursive(qc, L, l, mid, ppos, npos + [pos], pos - 1)\n        recursive(qc, L, mid, r, ppos + [pos], npos, pos - 1)\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    recursive(qc, L, 0, 2**n, [], [], n - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ABEA8FDA3C5F5", "submission_order": 1, "result": "AC", "execution_time": "2658 ms", "memory": "186 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AC185669EF24D", "submission_order": 1, "result": "RE", "execution_time": "964 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            continue\n        for j in range(i+1, n):\n            if not ((L>>j) & 1):\n                qc.x(j)\n        qc.x(i)\n        qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i+1, n):\n            if not ((L>>j) & 1):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AC185669EF24D", "submission_order": 2, "result": "AC", "execution_time": "1796 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            continue\n        for j in range(i+1, n):\n            if not ((L>>j) & 1):\n                qc.x(j)\n        qc.x(i)\n        if i == n-1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i+1, n):\n            if not ((L>>j) & 1):\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AC5A11814A5A1", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ACBDDEF386ED3", "submission_order": 1, "result": "DLE", "execution_time": "1016 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n      if L == 2:\n        qc.z(0)\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      return qc\n\n    s = range(n)\n    f = ZGate().control(n - 1)\n    for i in range(L):\n      for j in range(n):\n        if (i >> j) & 1:\n          continue\n        else:\n          qc.x(j)\n      qc.append(f, s)\n      for j in range(n):\n        if (i >> j) & 1:\n          continue\n        else:\n          qc.x(j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ACBDDEF386ED3", "submission_order": 2, "result": "WA", "execution_time": "1139 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n      if L == 2:\n        qc.z(0)\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      return qc\n\n    sum = 0;\n    for j in range(n - 1, -1, -1):\n      if sum + (1 << j) >= L:\n        for i in range(n - 1, j - 1, -1):\n          qc.x(i)\n        if j == n - 1:\n          qc.z(j)\n        else:\n          qc.append(ZGate().control(n - j - 1), range(n - 1, j - 1, -1))\n        for i in range(n - 1, j - 1, -1):\n          qc.x(i)\n        sum += (1 << j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ACBDDEF386ED3", "submission_order": 3, "result": "WA", "execution_time": "1095 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n      if L == 2:\n        qc.z(0)\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      return qc\n\n    sum = 0;\n    for j in range(n - 1, -1, -1):\n      if sum + (1 << j) <= L:\n        for i in range(n - 1, j - 1, -1):\n          qc.x(i)\n        if j == n - 1:\n          qc.z(j)\n        else:\n          qc.append(ZGate().control(n - j - 1), range(n - 1, j - 1, -1))\n        for i in range(n - 1, j - 1, -1):\n          qc.x(i)\n        sum += (1 << j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ACBDDEF386ED3", "submission_order": 4, "result": "AC", "execution_time": "2004 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n      if L == 2:\n        qc.z(0)\n      qc.x(0)\n      qc.z(0)\n      qc.x(0)\n      return qc\n\n    sum = 0;\n    for j in range(n - 1, -1, -1):\n      if sum + (1 << j) <= L:\n        for i in range(n - 1, j - 1, -1):\n          if (sum >> i) % 2 == 0: \n            qc.x(i)\n        if j == n - 1:\n          qc.z(j)\n        else:\n          qc.append(ZGate().control(n - j - 1), range(n - 1, j - 1, -1))\n        for i in range(n - 1, j - 1, -1):\n          if (sum >> i) % 2 == 0: \n            qc.x(i)\n        sum += (1 << j)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ACFB0DCC79EDC", "submission_order": 1, "result": "RE", "execution_time": "870 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i=n-1\n    p=[]\n    while(i>=0):\n        p.append(i)\n        if(L&(1<<i)):\n            qc.append(XGate(), [i])\n            if(i<n-1):\n                qc.append(ZGate().control(n-i-1), p)\n            else:\n                qc.append(ZGate(), p)\n            qc.append(XGate(), [i])\n        else:\n            qc.append(XGate(), [i])\n        i-=1\n    i=n-1\n    while(i>=0):\n        if((L&(1<<i))==0):\n            qc.append(XGate(), [i])\n        i-=1\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ACFB0DCC79EDC", "submission_order": 2, "result": "AC", "execution_time": "1356 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i=n-1\n    p=[]\n    while(i>=0):\n        p.append(i)\n        if(L&(1<<i)):\n            qc.append(XGate(), [i])\n            if(i<n-1):\n                qc.append(ZGate().control(n-i-1), p)\n            else:\n                qc.append(ZGate(), p)\n            qc.append(XGate(), [i])\n        else:\n            qc.append(XGate(), [i])\n        i-=1\n    i=n-1\n    while(i>=0):\n        if((L&(1<<i))==0):\n            qc.append(XGate(), [i])\n        i-=1\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD090234A39AC", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i+1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n-1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().continue(n-i-1).range(i, n))\n        qc.x(i)\n        for j in range(i+1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD090234A39AC", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i+1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n-1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().continue(n-i-1), range(i, n))\n        qc.x(i)\n        for j in range(i+1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD090234A39AC", "submission_order": 3, "result": "AC", "execution_time": "2635 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i+1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n-1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n-i-1), range(i, n))\n        qc.x(i)\n        for j in range(i+1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD1B5D44330CC", "submission_order": 1, "result": "DLE", "execution_time": "2523 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n\n    # 全部1になっている物を反転\n    def reverse(qubits,qc):\n        if qubits>1:\n            qc.append(ZGate().control(qubits - 1), range(qubits))\n        else:\n            qc.z(0)\n    \n    # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    for i in range(L):\n        to_calcable(n,qc,i)\n        reverse(n,qc)\n        to_calcable(n,qc,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD1B5D44330CC", "submission_order": 2, "result": "RE", "execution_time": "1468 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n\n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits>1:\n            qc.append(ZGate().control(qubits - 1 -start), range(start,qubits))\n        else:\n            qc.z(0)\n    \n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,n):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    for i in range(n):\n        if n&(1<<i):\n            to_calcable(n,qc,L,i)\n            reverse(n,qc)\n            to_calcable(n,qc,L,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD1B5D44330CC", "submission_order": 3, "result": "RE", "execution_time": "1391 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n\n    # 大きいほうの(qubits-start) bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 -start), range(start,qubits))\n        else:\n            qc.z(0)\n    \n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,n):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    for i in range(n):\n        if n&(1<<i):\n            to_calcable(n,qc,L,i)\n            reverse(n,qc,i)\n            to_calcable(n,qc,L,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD1B5D44330CC", "submission_order": 4, "result": "WA", "execution_time": "1377 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n\n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 -start), range(start,qubits))\n        else:\n            qc.z(0)\n    \n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    for i in range(n):\n        if n&(1<<i):\n            to_calcable(n,qc,L,i)\n            reverse(n,qc,i)\n            to_calcable(n,qc,L,i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD1B5D44330CC", "submission_order": 5, "result": "WA", "execution_time": "1674 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n,n)\n    \n\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 - start), range(start,qubits))\n        else:\n            qc.z(start)\n\n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    v=L-1\n    for i in range(n):\n        if L&(1<<i):\n            to_calcable(n,qc,v,i)\n            reverse(n,qc,i)\n            to_calcable(n,qc,v,i)\n            v-=(1<<i)\n\n\n    # to_calcable(n,qc,0,2)\n    # reverse(n,qc,2)\n    # to_calcable(n,qc,0,2)\n\n    # to_calcable(n,qc,4,1)\n    # reverse(n,qc,1)\n    # to_calcable(n,qc,4,1)\n\n    # to_calcable(n,qc,4,0)\n    # reverse(n,qc,0)\n    # to_calcable(n,qc,4,0)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD1B5D44330CC", "submission_order": 6, "result": "WA", "execution_time": "1660 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 - start), range(start,qubits))\n        else:\n            qc.z(start)\n\n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    v=L-1\n    for i in range(n):\n        if L&(1<<i):\n            to_calcable(n,qc,v,i)\n            reverse(n,qc,i)\n            to_calcable(n,qc,v,i)\n            v-=(1<<i)\n\n\n    # to_calcable(n,qc,0,2)\n    # reverse(n,qc,2)\n    # to_calcable(n,qc,0,2)\n\n    # to_calcable(n,qc,4,1)\n    # reverse(n,qc,1)\n    # to_calcable(n,qc,4,1)\n\n    # to_calcable(n,qc,4,0)\n    # reverse(n,qc,0)\n    # to_calcable(n,qc,4,0)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD1B5D44330CC", "submission_order": 7, "result": "AC", "execution_time": "2459 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n,n)\n    \n\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n    \n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 - start), range(start,qubits))\n        else:\n            qc.z(start)\n\n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    v=L-1\n    for i in range(n):\n        if L&(1<<i):\n            to_calcable(n,qc,v,i)\n            reverse(n,qc,i)\n            to_calcable(n,qc,v,i)\n            v-=(1<<i)\n\n\n    # to_calcable(n,qc,0,2)\n    # reverse(n,qc,2)\n    # to_calcable(n,qc,0,2)\n\n    # to_calcable(n,qc,4,1)\n    # reverse(n,qc,1)\n    # to_calcable(n,qc,4,1)\n\n    # to_calcable(n,qc,4,0)\n    # reverse(n,qc,0)\n    # to_calcable(n,qc,4,0)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD2F471B69576", "submission_order": 1, "result": "WA", "execution_time": "924 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    \n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L == 2:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n        return qc\n    qc.barrier()\n\n    \n    circuitlist = [\"O\" for i in range(n)]\n\n\n    for l_little in range(L):\n        binary_L_minus_1 = format(l_little, '0' + str(n) + 'b')[::-1]\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                if circuitlist[qubit][-1] == 'X':\n                    circuitlist[qubit] = circuitlist[qubit][:len(circuitlist[qubit])-1]\n                    \n                else:\n                    circuitlist[qubit] = circuitlist[qubit] + 'X'\n                #qc.x(qubit)\n        \n        #qc.h(n-1)\n        if circuitlist[n-1][-1] == 'H':\n            circuitlist[n-1] = circuitlist[n-1][:len(circuitlist[n-1])-1]\n        else:\n            circuitlist[n-1] = circuitlist[n-1] + 'H'\n\n        for i in range(n):\n            for s in range(len(circuitlist[i])):\n                if circuitlist[i][s] == 'H':\n                    qc.h(i)\n                elif circuitlist[i][s] == 'X':\n                    qc.x(i)\n        print(circuitlist)\n        circuitlist = [\"O\" for i in range(n)]\n        \n        qc.mcx(list(range(n-1)),n-1)\n        #qc.h(n-1)\n        if circuitlist[n-1][-1] == 'H':\n            circuitlist[n-1] = circuitlist[n-1][:len(circuitlist[n-1])-1]\n        else:\n            circuitlist[n-1] = circuitlist[n-1] + 'H'\n\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                #qc.x(qubit)\n                if circuitlist[qubit][-1] == 'X':\n                    circuitlist[qubit] = circuitlist[qubit][:len(circuitlist[qubit])-1]\n                else:\n                    circuitlist[qubit] = circuitlist[qubit] + 'X'\n        #qc.barrier()\n    for i in range(n):\n        for s in range(len(circuitlist[i])):\n            if circuitlist[i][s] == 'H':\n                qc.h(i)\n            elif circuitlist[i][s] == 'X':\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD2F471B69576", "submission_order": 2, "result": "WA", "execution_time": "1176 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    \n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L == 2:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n        return qc\n    qc.barrier()\n\n    \n    circuitlist = [\"O\" for i in range(n)]\n\n\n    for l_little in range(L):\n        binary_L_minus_1 = format(l_little, '0' + str(n) + 'b')[::-1]\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                if circuitlist[qubit][-1] == 'X':\n                    circuitlist[qubit] = circuitlist[qubit][:len(circuitlist[qubit])-1]\n                    \n                else:\n                    circuitlist[qubit] = circuitlist[qubit] + 'X'\n                #qc.x(qubit)\n        \n        #qc.h(n-1)\n        if circuitlist[n-1][-1] == 'H':\n            circuitlist[n-1] = circuitlist[n-1][:len(circuitlist[n-1])-1]\n        else:\n            circuitlist[n-1] = circuitlist[n-1] + 'H'\n\n        for i in range(n):\n            for s in range(len(circuitlist[i])):\n                if circuitlist[i][s] == 'H':\n                    qc.h(i)\n                elif circuitlist[i][s] == 'X':\n                    qc.x(i)\n        circuitlist = [\"O\" for i in range(n)]\n        \n        qc.mcx(list(range(n-1)),n-1)\n        #qc.h(n-1)\n        if circuitlist[n-1][-1] == 'H':\n            circuitlist[n-1] = circuitlist[n-1][:len(circuitlist[n-1])-1]\n        else:\n            circuitlist[n-1] = circuitlist[n-1] + 'H'\n\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                #qc.x(qubit)\n                if circuitlist[qubit][-1] == 'X':\n                    circuitlist[qubit] = circuitlist[qubit][:len(circuitlist[qubit])-1]\n                else:\n                    circuitlist[qubit] = circuitlist[qubit] + 'X'\n        #qc.barrier()\n    for i in range(n):\n        for s in range(len(circuitlist[i])):\n            if circuitlist[i][s] == 'H':\n                qc.h(i)\n            elif circuitlist[i][s] == 'X':\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD2F471B69576", "submission_order": 3, "result": "WA", "execution_time": "1159 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    \n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        if L == 2:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n        return qc\n    #qc.barrier()\n\n    \n    circuitlist = [\"O\" for i in range(n)]\n\n\n    for l_little in range(L):\n        binary_L_minus_1 = format(l_little, '0' + str(n) + 'b')[::-1]\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                if circuitlist[qubit][-1] == 'X':\n                    circuitlist[qubit] = circuitlist[qubit][:len(circuitlist[qubit])-1]\n                    \n                else:\n                    circuitlist[qubit] = circuitlist[qubit] + 'X'\n                #qc.x(qubit)\n        \n        #qc.h(n-1)\n        if circuitlist[n-1][-1] == 'H':\n            circuitlist[n-1] = circuitlist[n-1][:len(circuitlist[n-1])-1]\n        else:\n            circuitlist[n-1] = circuitlist[n-1] + 'H'\n\n        for i in range(n):\n            for s in range(len(circuitlist[i])):\n                if circuitlist[i][s] == 'H':\n                    qc.h(i)\n                elif circuitlist[i][s] == 'X':\n                    qc.x(i)\n        circuitlist = [\"O\" for i in range(n)]\n        \n        qc.mcx(list(range(n-1)),n-1)\n        #qc.h(n-1)\n        if circuitlist[n-1][-1] == 'H':\n            circuitlist[n-1] = circuitlist[n-1][:len(circuitlist[n-1])-1]\n        else:\n            circuitlist[n-1] = circuitlist[n-1] + 'H'\n\n        for qubit in range(n):\n            if binary_L_minus_1[qubit] == '0':\n                #qc.x(qubit)\n                if circuitlist[qubit][-1] == 'X':\n                    circuitlist[qubit] = circuitlist[qubit][:len(circuitlist[qubit])-1]\n                else:\n                    circuitlist[qubit] = circuitlist[qubit] + 'X'\n        #qc.barrier()\n    for i in range(n):\n        for s in range(len(circuitlist[i])):\n            if circuitlist[i][s] == 'H':\n                qc.h(i)\n            elif circuitlist[i][s] == 'X':\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD721685619E1", "submission_order": 1, "result": "RE", "execution_time": "1172 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n - 1, -1, -1):\n        for j in range(n - 1, i, -1):\n            qc.cp(np.pi / (2 ** (j - i)), j, i)\n        \n        qc.h(i)  # Hadamardゲートも逆順で適\n    \n    for i in range(n // 2):\n        qc.cx(i, n - i - 1)\n        qc.cx(i, n - i - 1)\n        qc.cx(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD80DF546444A", "submission_order": 1, "result": "RE", "execution_time": "1214 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n        if n>1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD80DF546444A", "submission_order": 2, "result": "RE", "execution_time": "1717 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n        if n>1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n    qc = transpile(qc, optimization_level=3)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD80DF546444A", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.compiler import transpile\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(L):\n        bin_data = format(i, f'0{n}b')        \n        data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n        if n>1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        if len(data_0_bits) > 0: \n            qc.x(data_0_bits)\n\n    qc = transpile(qc, optimization_level=3)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD80DF546444A", "submission_order": 4, "result": "RE", "execution_time": "1347 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    bin_data = format(L, f'0{n}b')        \n    set_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '1']\n    \n    for i in set_bits:\n\n        if i>0: \n            qc.h(range(i-1))\n\n        qc.x(i)\n\n        if n>1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        qc.x(i)\n\n        if i>0: \n            qc.h(range(i-1))\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD941ABC686C1", "submission_order": 1, "result": "RE", "execution_time": "920 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        else:\n            qc.z(0)\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        return qc\n   \n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    current_state = \"0\" *(n-bit_position[0]-1)\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        if n-pos-1 == 0:\n            qc.x(pos)\n            qc.z(pos)\n            qc.x(pos)\n        else:\n            custom = ZGate().control(n-pos-1,ctrl_state=current_state)\n            qc.x(pos)\n            qc.append(custom,list(range(n-1,pos-1,-1)))\n            qc.x(pos)\n        if i != len(bit_position)-1:    \n            current_state += \"1\" \n            current_state += \"0\" * (bit_position[i] - bit_position[i+1]-1)\n\n    while len(current_state) < n-1:\n        current_state += \"0\"\n    print(current_state)\n    print(list(range(n-1,pos,-1)) + list(range(pos)))\n    custom = ZGate().control(n-1,ctrl_state=current_state)\n    pos = bit_position[-1]\n    qc.append(custom,list(range(n-1,pos,-1)) + list(range(pos+1)))\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD941ABC686C1", "submission_order": 2, "result": "RE", "execution_time": "784 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n    if n == 1:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n   \n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    current_state = \"0\" *(n-bit_position[0]-1)\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        if n-pos-1 == 0:\n            qc.x(pos)\n            qc.z(pos)\n            qc.x(pos)\n        else:\n            custom = ZGate().control(n-pos-1,ctrl_state=current_state)\n            qc.x(pos)\n            qc.append(custom,list(range(n-1,pos-1,-1)))\n            qc.x(pos)\n        if i != len(bit_position)-1:    \n            current_state += \"1\" \n            current_state += \"0\" * (bit_position[i] - bit_position[i+1]-1)\n\n    while len(current_state) < n-1:\n        current_state += \"0\"\n    custom = ZGate().control(n-1,ctrl_state=current_state)\n    pos = bit_position[-1]\n    qc.append(custom,list(range(n-1,pos,-1)) + list(range(pos+1)))\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD941ABC686C1", "submission_order": 3, "result": "WA", "execution_time": "1112 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n    if n == 1:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n   \n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    current_state = \"0\" *(n-bit_position[0]-1)\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        if n-pos-1 == 0:\n            qc.x(pos)\n            qc.z(pos)\n            qc.x(pos)\n        else:\n            custom = ZGate().control(n-pos-1,ctrl_state=current_state)\n            qc.x(pos)\n            qc.append(custom,list(range(n-1,pos-1,-1)))\n            qc.x(pos)\n        if i != len(bit_position)-1:    \n            current_state += \"1\" \n            current_state += \"0\" * (bit_position[i] - bit_position[i+1]-1)\n\n    while len(current_state) < n-1:\n        current_state += \"0\"\n    custom = ZGate().control(n-1,ctrl_state=current_state)\n    pos = bit_position[-1]\n    qc.append(custom,list(range(n-1,pos,-1)) + list(range(pos+1)))\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD941ABC686C1", "submission_order": 4, "result": "WA", "execution_time": "1113 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n    if n == 1:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n   \n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    current_state = \"0\" *(n-bit_position[0]-1)\n    # print(current_state)\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        if n-pos-1 == 0:\n            qc.x(pos)\n            qc.z(pos)\n            qc.x(pos)\n        else:\n            custom = ZGate().control(n-pos-1,ctrl_state=current_state)\n            qc.x(pos)\n            # print(list(range(n-1,pos-1,-1)))\n            qc.append(custom,list(range(n-1,pos-1,-1)))\n            qc.x(pos)\n        if i==1:\n            break\n        if i != len(bit_position)-1:    \n            current_state = \"1\" + current_state\n            current_state = \"0\" * (bit_position[i] - bit_position[i+1]-1) + current_state\n            print(current_state)\n    while len(current_state) < n-1:\n        current_state = \"0\" + current_state\n    # print(current_state)\n    # print(list(range(n-1,pos,-1)) + list(range(pos)))\n    custom = ZGate().control(n-1,ctrl_state=current_state)\n    pos = bit_position[-1]\n    qc.append(custom,list(range(n-1,pos,-1)) + list(range(pos+1)))\n    # print(qc.depth())\n    # print(qc)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD941ABC686C1", "submission_order": 5, "result": "WA", "execution_time": "1132 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n    if n == 1:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n   \n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    current_state = \"0\" *(n-bit_position[0]-1)\n    # print(current_state)\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        if n-pos-1 == 0:\n            qc.x(pos)\n            qc.z(pos)\n            qc.x(pos)\n        else:\n            custom = ZGate().control(n-pos-1,ctrl_state=current_state)\n            qc.x(pos)\n            # print(list(range(n-1,pos-1,-1)))\n            qc.append(custom,list(range(n-1,pos-1,-1)))\n            qc.x(pos)\n        if i != len(bit_position)-1:    \n            current_state = \"1\" + current_state\n            current_state = \"0\" * (bit_position[i] - bit_position[i+1]-1) + current_state\n            print(current_state)\n    while len(current_state) < n-1:\n        current_state = \"0\" + current_state\n    # print(current_state)\n    # print(list(range(n-1,pos,-1)) + list(range(pos)))\n    custom = ZGate().control(n-1,ctrl_state=current_state)\n    pos = bit_position[-1]\n    qc.append(custom,list(range(n-1,pos,-1)) + list(range(pos+1)))\n    # print(qc.depth())\n    # print(qc)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD941ABC686C1", "submission_order": 6, "result": "RE", "execution_time": "1237 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        qc.x(0)\n        custom = ZGate().control(n-1,\"0\"*(n-1))\n        qc.append(custom,list(range(n-1,-1,-1)))\n        qc.x(0)\n        return qc\n    if n == 1:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n   \n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    current_state = \"0\" *(n-bit_position[0]-1)\n    # print(current_state)\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        if n-pos-1 == 0:\n            qc.x(pos)\n            qc.z(pos)\n            qc.x(pos)\n        else:\n            custom = ZGate().control(n-pos-1,ctrl_state=current_state)\n            qc.x(pos)\n            # print(list(range(n-1,pos-1,-1)))\n            qc.append(custom,list(range(n-1,pos-1,-1)))\n            qc.x(pos)\n        if i != len(bit_position)-1:    \n            current_state = \"1\" + current_state\n            current_state = \"0\" * (bit_position[i] - bit_position[i+1]-1) + current_state\n            print(current_state)\n    while len(current_state) < n-1:\n        current_state = \"0\" + current_state\n    # print(current_state)\n    # print(list(range(n-1,pos,-1)) + list(range(pos)))\n    custom = ZGate().control(n-1,ctrl_state=current_state)\n    pos = bit_position[-1]\n    qc.append(custom,list(range(n-1,pos,-1)) + list(range(pos+1)))\n    # print(qc.depth())\n    # print(qc)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD941ABC686C1", "submission_order": 7, "result": "WA", "execution_time": "1196 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        if n==1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        else:\n            qc.x(0)\n            custom = ZGate().control(n-1,\"0\"*(n-1))\n            qc.append(custom,list(range(n-1,-1,-1)))\n            qc.x(0)\n        return qc\n    if n == 1:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n   \n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    current_state = \"0\" *(n-bit_position[0]-1)\n    # print(current_state)\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        if n-pos-1 == 0:\n            qc.x(pos)\n            qc.z(pos)\n            qc.x(pos)\n        else:\n            custom = ZGate().control(n-pos-1,ctrl_state=current_state)\n            qc.x(pos)\n            # print(list(range(n-1,pos-1,-1)))\n            qc.append(custom,list(range(n-1,pos-1,-1)))\n            qc.x(pos)\n        if i != len(bit_position)-1:    \n            current_state = \"1\" + current_state\n            current_state = \"0\" * (bit_position[i] - bit_position[i+1]-1) + current_state\n            print(current_state)\n    while len(current_state) < n-1:\n        current_state = \"0\" + current_state\n    # print(current_state)\n    # print(list(range(n-1,pos,-1)) + list(range(pos)))\n    custom = ZGate().control(n-1,ctrl_state=current_state)\n    pos = bit_position[-1]\n    qc.append(custom,list(range(n-1,pos,-1)) + list(range(pos+1)))\n    # print(qc.depth())\n    # print(qc)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AD941ABC686C1", "submission_order": 8, "result": "AC", "execution_time": "1518 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        if n==1:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n        else:\n            qc.x(0)\n            custom = ZGate().control(n-1,ctrl_state=\"0\"*(n-1))\n            qc.append(custom,list(range(n-1,-1,-1)))\n            qc.x(0)\n        return qc\n    if n == 1:\n        qc.z(0)\n        qc.x(0)\n        qc.z(0)\n        qc.x(0)\n        return qc\n   \n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    current_state = \"0\" *(n-bit_position[0]-1)\n    # print(current_state)\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        if n-pos-1 == 0:\n            qc.x(pos)\n            qc.z(pos)\n            qc.x(pos)\n        else:\n            custom = ZGate().control(n-pos-1,ctrl_state=current_state)\n            qc.x(pos)\n            # print(list(range(n-1,pos-1,-1)))\n            qc.append(custom,list(range(n-1,pos-1,-1)))\n            qc.x(pos)\n        if i != len(bit_position)-1:    \n            current_state = \"1\" + current_state\n            current_state = \"0\" * (bit_position[i] - bit_position[i+1]-1) + current_state\n            print(current_state)\n    while len(current_state) < n-1:\n        current_state = \"0\" + current_state\n    # print(current_state)\n    # print(list(range(n-1,pos,-1)) + list(range(pos)))\n    custom = ZGate().control(n-1,ctrl_state=current_state)\n    pos = bit_position[-1]\n    qc.append(custom,list(range(n-1,pos,-1)) + list(range(pos+1)))\n    # print(qc.depth())\n    # print(qc)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ADCB99F0E1DE4", "submission_order": 1, "result": "DLE", "execution_time": "1619 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(L):\n        append_gate = lambda gate: qc.append(gate(), [0]) if n == 1 else \\\n                qc.append(gate().control(n - 1, ctrl_state = i & ((1 << n - 1) - 1)), range(n))\n        if not (i >> n - 1 & 1):\n            append_gate(XGate)\n        append_gate(ZGate)\n        if not (i >> n - 1 & 1):\n            append_gate(XGate)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "ADCB99F0E1DE4", "submission_order": 2, "result": "AC", "execution_time": "2100 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    msk = 0\n    for k in range(n - 1, -1, -1):\n        append_gate = lambda gate: qc.append(gate(), [k]) if n - k - 1 == 0 else \\\n                    qc.append(gate().control(n - k - 1, ctrl_state=msk), list(range(k + 1, n)) + [k])\n        if L >> k & 1:\n            append_gate(XGate)\n            append_gate(ZGate)\n            append_gate(XGate)\n            msk = (msk << 1) ^ 1\n        else:\n            msk <<= 1\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 1, "result": "DLE", "execution_time": "1410 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for maska in range(L):\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n        if (n == 1):\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n-1),range(n))\n        for i in range(n):\n            if (not (maska&(1<<i))):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import *\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0;\n    sufiksik = []\n    for i in range(n-1,-1,-1):\n        sufiksik.append(i)\n        print(i,(1<<(n-i-1)))\n        if (L&(1<<i)):\n            print(\"sufiks1: \",sufiks)\n            sufiks += (1<<(n-i-1))\n        else:\n            print(\"ZGate: \",sufiks, n-i-1)\n            for x in sufiksik:\n                print(x,end=\" \")\n            qc.append(ZGate().control(n-i-1),sufiksik)\n    for i in range(n):\n        qc.z(i)\n        for j in range(n):\n            if i != j:\n                qc.cz(i,j)\n        qc.z(i)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 3, "result": "RE", "execution_time": "753 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0;\n    sufiksik = []\n    for i in range(n-1,-1,-1):\n        sufiksik.append(i)\n        print(i,(1<<(n-i-1)))\n        if (L&(1<<i)):\n            print(\"sufiks1: \",sufiks)\n            sufiks += (1<<(n-i-1))\n        else:\n            print(\"ZGate: \",sufiks, n-i-1)\n            for x in sufiksik:\n                print(x,end=\" \")\n            qc.append(ZGate().control(n-i-1),sufiksik)\n    for i in range(n):\n        qc.z(i)\n        for j in range(n):\n            if i != j:\n                qc.cz(i,j)\n        qc.z(i)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 4, "result": "RE", "execution_time": "736 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0;\n    sufiksik = []\n    for i in range(n-1,-1,-1):\n        sufiksik.append(i)\n        print(i,(1<<(n-i-1)))\n        if (L&(1<<i)):\n            sufiks += (1<<(n-i-1))\n        else:\n            qc.append(ZGate().control(n-i-1),sufiksik)\n    for i in range(n):\n        qc.z(i)\n        for j in range(n):\n            if i != j:\n                qc.cz(i,j)\n        qc.z(i)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 5, "result": "RE", "execution_time": "753 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0;\n    sufiksik = []\n    for i in range(n-1,-1,-1):\n        sufiksik.append(i)\n        if (L&(1<<i)):\n            sufiks += (1<<(n-i-1))\n        else:\n            qc.append(ZGate().control(n-i-1),sufiksik)\n    for i in range(n):\n        qc.z(i)\n        for j in range(n):\n            if i != j:\n                qc.cz(i,j)\n        qc.z(i)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 6, "result": "WA", "execution_time": "921 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0;\n    sufiksik = []\n    #for i in range(n-1,-1,-1):\n     #   sufiksik.append(i)\n      #  if (L&(1<<i)):\n       #     sufiks += (1<<(n-i-1))\n        #else:\n         #   qc.append(ZGate().control(n-i-1),sufiksik)\n    for i in range(n):\n        qc.z(i)\n        for j in range(n):\n            if i != j:\n                qc.cz(i,j)\n        qc.z(i)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 7, "result": "WA", "execution_time": "808 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0;\n    sufiksik = []\n   # for i in range(n-1,-1,-1):\n    #    sufiksik.append(i)\n     #   if (L&(1<<i)):\n      #      sufiks += (1<<(n-i-1))\n       # else:\n        #    qc.append(ZGate().control(n-i-1),sufiksik)\n    for i in range(n):\n        for j in range(i-1):\n            qc.z(j)\n            qc.cz(j,i)\n            qc.z(j)\n    for i in range(n-1,-1,-1):\n        for j in range(i+1,n):\n            qc.z(j)\n            qc.cz(j,i)\n            qc.z(j)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 8, "result": "RE", "execution_time": "722 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0\n    sufiksik = []\n    for i in range(n-1,-1,-1):\n        sufiksik.push_back(i)\n        if (L&(1<<i)):\n            sufiks += (1<<(n-i-1))\n        else:\n            qc.append(ZGate().control(n-i-1),sufiksik)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 9, "result": "RE", "execution_time": "758 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0\n    sufiksik = []\n    for i in range(n-1,-1,-1):\n        sufiksik.push_back(i)\n        if (L&(1<<i)):\n            sufiks += (1<<(n-i-1))\n        else:\n            if (i != n-1):\n                qc.append(ZGate().control(n-i-1),sufiksik)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E010C0A437", "submission_order": 10, "result": "RE", "execution_time": "697 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    sufiks = 0\n    sufiksik = []\n    for i in range(n-1,-1,-1):\n        sufiksik.append(i)\n        if (L&(1<<i)):\n            sufiks += (1<<(n-i-1))\n        else:\n            qc.append(ZGate().control(n-i-1),sufiksik)\n    #print(qc)\n    return qc\n#solve(10,567)\n'''"}
{"problem": "QPC001_B4", "user": "AE1E1E842AA9B", "submission_order": 1, "result": "AC", "execution_time": "2890 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    same = ''\n    for i in range(n-1, -1, -1):\n        nxt = L >> i & 1\n        if nxt == 1:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n-i-1, ctrl_state=same), range(n-1, i-1, -1))\n                qc.x(i)\n        same = str(nxt) + same\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_B4", "user": "AE2C60757630F", "submission_order": 1, "result": "RE", "execution_time": "2420 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bitstring = ''\n    controls = []\n    for i in range(n-1, -1, -1):\n        msb = (L >> i) & 1\n        L = L & (2 ** i - 1)\n        qc.mcp(pi, controls, i, ctrl_state=bitstring)\n        controls.append(i)\n        bitstring = bitstring + str(msb)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE2C60757630F", "submission_order": 2, "result": "WA", "execution_time": "1821 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bitstring = ''\n    controls = []\n    L = 2 ** n - L\n    for i in range(n-1, -1, -1):\n        msb = (L >> i) & 1\n        L = L & (2 ** i - 1)\n        if msb == 1:\n            if not controls:\n                qc.p(pi, i)\n            else:\n                qc.mcp(pi, controls, i, ctrl_state=bitstring)\n        controls.append(i)\n        bitstring = bitstring + str(msb)\n\n        return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE2C60757630F", "submission_order": 3, "result": "AC", "execution_time": "2163 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bitstring = ''\n    controls = []\n    L = 2 ** n - L\n    for i in range(n-1, -1, -1):\n        msb = (L >> i) & 1\n        L = L & (2 ** i - 1)\n        print(i, msb, bitstring, controls)\n        if msb == 1:\n            if not controls:\n                qc.p(pi, i)\n            else:\n                qc.mcp(pi, controls, i, ctrl_state=bitstring)\n        controls.append(i)\n        bitstring = str(1 - msb) + bitstring\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE3D479569762", "submission_order": 1, "result": "RE", "execution_time": "1258 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(L & (1<<i)):\n            for j in range(i-1):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n            if i == 0:\n                qc.z(0)\n            else:\n                qc.append(ZGate().control(i), range(i+1))\n            for j in range(i-1):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE3D479569762", "submission_order": 2, "result": "WA", "execution_time": "1284 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(L & (1<<i)):\n            for j in range(i):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n            if i == 0:\n                qc.z(0)\n            else:\n                qc.append(ZGate().control(i), range(i+1))\n            for j in range(i):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE3D479569762", "submission_order": 3, "result": "WA", "execution_time": "2082 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(L & (1<<i)):\n            for j in range(i+1, n):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n            if i == n-1:\n                qc.z(0)\n            else:\n                qc.append(ZGate().control(n-i-1), range(i,n))\n            for j in range(i+1, n):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE3D479569762", "submission_order": 4, "result": "WA", "execution_time": "1317 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(L & (1<<i)):\n            for j in range(i+1, n):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n            if i == n-1:\n                qc.z(i)\n            else:\n                qc.append(ZGate().control(n-i-1), range(i,n))\n            for j in range(i+1, ):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE3D479569762", "submission_order": 5, "result": "AC", "execution_time": "2435 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if(L & (1<<i)):\n            for j in range(i+1, n):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n            if i == n-1:\n                qc.z(i)\n            else:\n                qc.append(ZGate().control(n-i-1), range(i,n))\n            for j in range(i+1, n):\n                if(not (L & (1<<j))):\n                    qc.x(j)\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE752EC31EC58", "submission_order": 1, "result": "DLE", "execution_time": "1053 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #    qc.h(i)\n    def xmap(m: int, size: int) -> list[int]:\n         a = []\n         idx = 0\n         while m:\n             if m % 2:\n                 a.append(idx)\n             idx += 1\n             m //= 2\n         return [i for i in range(size) if i not in a]\n    for i in range(L, 2**n):\n        a = xmap(i, n)\n        if a:\n            qc.x(a)\n        if n > 1:\n            qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n        else:\n            qc.z(0)\n        if a:\n            qc.x(a)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE752EC31EC58", "submission_order": 2, "result": "RE", "execution_time": "993 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    def to_bin(m: int, size: int) -> list[int]:\n        a = [0] * size\n        idx = 0\n        while m:\n            if m % 2:\n                a[idx] = 1\n            idx += 1\n            m //= 2\n        return a\n\n    def xmap(m: int, size: int) -> list[int]:\n        a = []\n        idx = 0\n        while m:\n            if m % 2:\n                a.append(idx)\n            idx += 1\n            m //= 2\n        return [i for i in range(size) if i not in a]\n        \n    def mcz(qc: QuantumCircuit, regs: list[int]) -> None:\n        if len(regs) == 0:\n            return\n        if len(regs) == 1:\n            qc.z(regs[0])\n        else:\n            qc.h(regs[-1])\n            qc.mcx(regs[:-1], regs[-1])\n            qc.h(regs[-1])\n\n    def xmcz(qc: QuantumCircuit, xregs: list[int], zregs: list[int]) -> None:\n        if xregs:\n            qc.x(xregs)\n        mcz(qc, zregs)\n        if xregs:\n            qc.x(xregs)\n\n    a = to_bin(L, n)\n    xs = xmap(L, n)\n    #print(xs)\n    for i in range(n):\n        if a[n - 1 - i] == 0:\n            #print(\"xmcz\", [x for x in xs if x > n - 1 - i], list(range(n - 1 - i, n)))\n            xmcz(qc, [x for x in xs if x > n - 1 - i], list(range(n - 1 - i, n)))\n    xmcz(qc, xs, list(range(n)))\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE752EC31EC58", "submission_order": 3, "result": "RE", "execution_time": "770 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def to_bin(m: int, size: int) -> list[int]:\n        a = [0] * size\n        idx = 0\n        while m:\n            if m % 2:\n                a[idx] = 1\n            idx += 1\n            m //= 2\n        return a\n\n    def xmap(m: int, size: int) -> list[int]:\n        a = []\n        idx = 0\n        while m:\n            if m % 2:\n                a.append(idx)\n            idx += 1\n            m //= 2\n        return [i for i in range(size) if i not in a]\n        \n    def mcz(qc: QuantumCircuit, regs: list[int]) -> None:\n        if len(regs) == 0:\n            return\n        if len(regs) == 1:\n            qc.z(regs[0])\n        else:\n            qc.h(regs[-1])\n            qc.mcx(regs[:-1], regs[-1])\n            qc.h(regs[-1])\n\n    def xmcz(qc: QuantumCircuit, xregs: list[int], zregs: list[int]) -> None:\n        if xregs:\n            qc.x(xregs)\n        mcz(qc, zregs)\n        if xregs:\n            qc.x(xregs)\n\n    a = to_bin(L, n)\n    xs = xmap(L, n)\n    #print(xs)\n    for i in range(n):\n        if a[n - 1 - i] == 0:\n            #print(\"xmcz\", [x for x in xs if x > n - 1 - i], list(range(n - 1 - i, n)))\n            xmcz(qc, [x for x in xs if x > n - 1 - i], list(range(n - 1 - i, n)))\n    xmcz(qc, xs, list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AE752EC31EC58", "submission_order": 4, "result": "AC", "execution_time": "1025 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 2**n:\n        return qc\n    def to_bin(m: int, size: int) -> list[int]:\n        a = [0] * size\n        idx = 0\n        while m:\n            if m % 2:\n                a[idx] = 1\n            idx += 1\n            m //= 2\n        return a\n\n    def xmap(m: int, size: int) -> list[int]:\n        a = []\n        idx = 0\n        while m:\n            if m % 2:\n                a.append(idx)\n            idx += 1\n            m //= 2\n        return [i for i in range(size) if i not in a]\n        \n    def mcz(qc: QuantumCircuit, regs: list[int]) -> None:\n        if len(regs) == 0:\n            return\n        if len(regs) == 1:\n            qc.z(regs[0])\n        else:\n            qc.h(regs[-1])\n            qc.mcx(regs[:-1], regs[-1])\n            qc.h(regs[-1])\n\n    def xmcz(qc: QuantumCircuit, xregs: list[int], zregs: list[int]) -> None:\n        if xregs:\n            qc.x(xregs)\n        mcz(qc, zregs)\n        if xregs:\n            qc.x(xregs)\n\n    a = to_bin(L, n)\n    xs = xmap(L, n)\n    #print(xs)\n    for i in range(n):\n        if a[n - 1 - i] == 0:\n            #print(\"xmcz\", [x for x in xs if x > n - 1 - i], list(range(n - 1 - i, n)))\n            xmcz(qc, [x for x in xs if x > n - 1 - i], list(range(n - 1 - i, n)))\n    xmcz(qc, xs, list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEA61F41880B3", "submission_order": 1, "result": "AC", "execution_time": "1628 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        if L&(1<<i)==0:\n            continue\n        for j in range(n-1,i,-1):\n            if L&(1<<j)==0:\n                qc.x(j)\n        \n        qc.x(i)\n        if i==n-1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n-i-1),range(n-1,i-1,-1))\n        \n        for j in range(n-1,i,-1):\n            if L&(1<<j)==0:\n                qc.x(j)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEACFA5CC2D0B", "submission_order": 1, "result": "AC", "execution_time": "2373 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.barrier()\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEC41F32AC37E", "submission_order": 1, "result": "RE", "execution_time": "1222 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if((L>>j) & 1):\n            for j in range(i+1,n):\n                if not ((L>>j) & 1):\n                    qc.x(j)\n        qc.x(i)\n        if( i == n-1):\n            qc.z(i)\n        else:\n            qc.append(Zgate().control(n-i-1),range(i,n))\n        qc.x(i)\n        for j in range(i+1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEC41F32AC37E", "submission_order": 2, "result": "RE", "execution_time": "1148 ms", "memory": "147 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if((L>>i) & 1):\n            for j in range(i+1,n):\n                if not ((L>>j) & 1):\n                    qc.x(j)\n            qc.x(i)\n            if( i == n-1):\n                qc.z(i)\n            else:\n                qc.append(Zgate().control(n-i-1),range(i,n))\n            qc.x(i)\n            for j in range(i+1, n):\n                if not (L >> j) & 1:\n                    qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEC41F32AC37E", "submission_order": 3, "result": "AC", "execution_time": "1867 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if((L>>i) & 1):\n            for j in range(i+1,n):\n                if not ((L>>j) & 1):\n                    qc.x(j)\n            qc.x(i)\n            if( i == n-1):\n                qc.z(i)\n            else:\n                qc.append(ZGate().control(n-i-1),range(i,n))\n            qc.x(i)\n            for j in range(i+1, n):\n                if not (L >> j) & 1:\n                    qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEC99D192C6DE", "submission_order": 1, "result": "RE", "execution_time": "809 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    cnz = ZGate().control(n - 1)\n    skip_idx = []\n    first = [True for _ in range(n)]\n    for d in reversed(range(n)):\n        if (L>>d)&1:\n            flip = L&(((1<<n)-1)-((1<<d)-1))\n            if d > 0:\n                flip -= 1\n            for i in range(n):\n                if (not (i in skip_idx) or first[i]) and ((flip>>i)&1) == 0:\n                    qc.x(i)\n                    first[i] = False\n            qc.append(cnz, range(n))\n            for i in range(n):\n                if (not (i in skip_idx) or first[i]) and ((flip>>i)&1) == 0:\n                    qc.x(i)\n                    first[i] = False\n        else:\n            skip_idx.append(d)\n            \n    for i in skip_idx:\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEC99D192C6DE", "submission_order": 2, "result": "RE", "execution_time": "821 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef flip_single_state(n: int, k: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    print('n: ', n, ' k: ', k)\n    for i in range(n):\n        if ((k>>i)&1) == 0:\n            qc.x(i)\n    qc.append(ZGate().control(n-1), range(n))\n    for i in range(n):\n        if ((k>>i)&1) == 0:\n            qc.x(i)\n    return qc\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for d in reversed(range(n)):\n        if (L>>d)&1:\n            flip = (L>>d)-1\n            fss = flip_single_state(n-d, flip)\n            #fss.draw('mpl', style='iqp')\n            qc.append(fss.to_gate(), range(d, n))\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEC99D192C6DE", "submission_order": 3, "result": "RE", "execution_time": "949 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for d in reversed(range(n)):\n        if (L>>d)&1:\n            flip = (L>>d)-1\n            for i in range(n-d):\n                if ((flip>>i)&1) == 0:\n                    qc.x(i+d)\n            qc.append(ZGate().control(n-d-1), range(d, n))\n            for i in range(n-d):\n                if ((flip>>i)&1) == 0:\n                    qc.x(i+d)\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEC99D192C6DE", "submission_order": 4, "result": "AC", "execution_time": "1191 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for d in reversed(range(n)):\n        if (L>>d)&1:\n            flip = (L>>d)-1\n            for i in range(n-d):\n                if ((flip>>i)&1) == 0:\n                    qc.x(i+d)\n            if n == d + 1:\n                qc.z(d)\n            else:\n                qc.append(ZGate().control(n-d-1), range(d, n))\n            for i in range(n-d):\n                if ((flip>>i)&1) == 0:\n                    qc.x(i+d)\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEDAB9029B257", "submission_order": 1, "result": "WA", "execution_time": "1763 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef mcz(qc: QuantumCircuit, cs: list[int]):\n    if len(cs) == 0:\n        return\n    if len(cs) == 1:\n        qc.z(cs[0])\n    else:\n        mcz_gate = ZGate().control(len(cs) - 1)\n        qc.append(mcz_gate, cs)\n\n# val = 2^k のとき\ndef num_inv_2(qc: QuantumCircuit, n: int, k: int):\n    qc.x(range(k, n))\n    mcz(qc, list(range(k, n)))\n    qc.x(range(k, n))\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(range(n))\n\n    for i in range(n):\n        if (L >> i) & 1:\n            qc.x(i)\n            num_inv_2(qc, n, i)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEDAB9029B257", "submission_order": 2, "result": "WA", "execution_time": "1639 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef mcz(qc: QuantumCircuit, cs: list[int]):\n    if len(cs) == 0:\n        return\n    if len(cs) == 1:\n        qc.z(cs[0])\n    else:\n        mcz_gate = ZGate().control(len(cs) - 1)\n        qc.append(mcz_gate, cs)\n\n# val = 2^k のとき\ndef num_inv_2(qc: QuantumCircuit, n: int, k: int):\n    qc.x(range(k, n))\n    mcz(qc, list(range(k, n)))\n    qc.x(range(k, n))\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # qc.h(range(n))\n\n    for i in range(n):\n        if (L >> i) & 1:\n            qc.x(i)\n            num_inv_2(qc, n, i)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEDAB9029B257", "submission_order": 3, "result": "AC", "execution_time": "1915 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef mcz(qc: QuantumCircuit, cs: list[int]):\n    if len(cs) == 1:\n        qc.z(cs[0])\n    else:\n        mcz_gate = ZGate().control(len(cs) - 1)\n        qc.append(mcz_gate, cs)\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # qc.h(range(n))\n\n    for i in range(n):\n        if (L >> i) & 1 == 0:\n            continue\n\n        # flip\n        qc.x(i)\n        for j in range(i + 1, n):\n            if (L >> j) & 1 == 0:\n                qc.x(j)\n        \n        mcz(qc, list(range(i, n)))\n        \n        # flip\n        qc.x(i)\n        for j in range(i + 1, n):\n            if (L >> j) & 1 == 0:\n                qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AEFAEC7D7DEFC", "submission_order": 1, "result": "DLE", "execution_time": "2625 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L):\n        log=[]\n        for j,x in enumerate(f\"{i:0{n}b}\"[::-1]):\n            if x==\"0\":\n                log.append(j)\n                qc.x(j)\n\n        if n!=1:\n            qc.append(ZGate().control(n-1), range(n))\n        else:\n            qc.z(0)\n\n        for j in log:\n            qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AF2A40871D818", "submission_order": 1, "result": "AC", "execution_time": "2472 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\ndef append_cz(qc, ctrl_lst, tgt):\n    if ctrl_lst:\n        qc.append(ZGate().control(len(ctrl_lst)), ctrl_lst+[tgt])\n    else:\n        qc.z(tgt)\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        # if i == n - 1:\n        #     qc.z(i)\n        # else:\n        #     qc.append(ZGate().control(n - i - 1), range(i, n))\n        append_cz(qc, [_ for _ in range(i, n-1)], n-1)\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AF8069F734A36", "submission_order": 1, "result": "WA", "execution_time": "933 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\n\nPI = math.pi\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 0:\n            return qc\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            return qc\n\n    for marked in range(L):\n        if marked == 0:\n            for i in range(n):\n                qc.x(i)\n            # apply MCZ\n            qc.mcp(PI, [qbit for qbit in range(n-1)], n-1)\n        else:\n            for apply_x_bit in range(n):\n                if marked & (1<<apply_x_bit) == 0 and not((marked-1) & (1<<apply_x_bit) == 0):\n                    qc.x(apply_x_bit)\n                elif not(marked & (1<<apply_x_bit) == 0) and (marked-1) & (1<<apply_x_bit) == 0:\n                    qc.x(apply_x_bit)\n            # apply MCZ\n            qc.mcp(PI, [qbit for qbit in range(n-1)], n-1)\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AF8069F734A36", "submission_order": 2, "result": "WA", "execution_time": "965 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\nPI = math.pi\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 0:\n            return qc\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            return qc\n\n    for marked in range(L):\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(PI, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AF8069F734A36", "submission_order": 3, "result": "WA", "execution_time": "1041 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\nPI = math.pi\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 0:\n            return qc\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            return qc\n\n    for marked in range(L):\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(PI, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n \n    return qc\n'''"}
{"problem": "QPC001_B4", "user": "AF8069F734A36", "submission_order": 4, "result": "RE", "execution_time": "926 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\nPI = math.pi\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 0:\n            return qc\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            return qc\n\n    for marked in range(L):\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(PI, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n \n    return qc.decompose(rep=5)\n'''"}
{"problem": "QPC001_B4", "user": "AF8069F734A36", "submission_order": 5, "result": "WA", "execution_time": "849 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\nimport math\n\nPI = math.pi\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 1:\n        if L == 0:\n            return qc\n        else:\n            qc.x(0)\n            qc.z(0)\n            qc.x(0)\n            return qc\n\n    for marked in range(L):\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n        # apply MCZ\n        qc.mcp(PI, [qbit for qbit in range(n-1)], n-1)\n        for zero_bit in range(n):\n            if marked & (1<<zero_bit) == 0:\n                qc.x(zero_bit)\n \n    return qc.decompose(reps=5)\n'''"}
{"problem": "QPC001_C1", "user": "A026D05469C2F", "submission_order": 1, "result": "AC", "execution_time": "1768 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    k = 0\n    while True:\n        qc.h(k)\n        k += 1\n        if (1<<k) >= L:\n            break\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 1, "result": "UGE", "execution_time": "1198 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                '''\n                cnh = MCMT('h',len(v),1)\n                qc.compose(cnh,qubits=range(n - 1, (n - 1) - len(v) - 1, -1),inplace=True)\n                '''\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            '''   \n            qc.x(j)\n            for k in range(j):\n                qc.ch(j, k)\n            qc.x(j)\n            '''\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 2, "result": "RE", "execution_time": "1206 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                '''\n                cnh = MCMT('h',len(v),1)\n                qc.compose(cnh,qubits=range(n - 1, (n - 1) - len(v) - 1, -1),inplace=True)\n                '''\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            '''   \n            qc.x(j)\n            for k in range(j):\n                qc.ch(j, k)\n            qc.x(j)\n            '''\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 3, "result": "WA", "execution_time": "1177 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                '''\n                cnh = MCMT('h',len(v),1)\n                qc.compose(cnh,qubits=range(n - 1, (n - 1) - len(v) - 1, -1),inplace=True)\n                '''\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            '''   \n            qc.x(j)\n            for k in range(j):\n                qc.ch(j, k)\n            qc.x(j)\n            '''\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 4, "result": "RE", "execution_time": "902 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                '''\n                cnh = MCMT('h',len(v),1)\n                qc.compose(cnh,qubits=range(n - 1, (n - 1) - len(v) - 1, -1),inplace=True)\n                '''\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            '''   \n            qc.x(j)\n            for k in range(j):\n                qc.ch(j, k)\n            qc.x(j)\n            '''\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 5, "result": "UGE", "execution_time": "1395 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 6, "result": "RE", "execution_time": "932 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n#                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 7, "result": "WA", "execution_time": "1177 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n                pass\n#                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 8, "result": "WA", "execution_time": "951 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n#                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n                pass\n#                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 9, "result": "WA", "execution_time": "1122 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n#                qc.mcrx(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n                pass\n                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A04C4F3B23F97", "submission_order": 10, "result": "AC", "execution_time": "2946 ms", "memory": "106 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                cnh = MCMT('h', (n - 1) - j,1)\n                qc.compose(cnh,qubits = list(range(n - 1, j - 1, -1)),inplace=True)\n                qc.mcp(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                cnh = MCMT('h', (n - 1) - j,1)\n                qc.compose(cnh,qubits = list(range(n - 1, j - 1, -1)),inplace=True)\n                \n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0908371EB7C9", "submission_order": 1, "result": "RE", "execution_time": "2114 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(math.ceil(math.log2(L))))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0908371EB7C9", "submission_order": 2, "result": "AC", "execution_time": "2166 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 1:\n        return qc\n    qc.h(range(math.ceil(math.log2(L))))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A09E90DF6C8E4", "submission_order": 1, "result": "UGE", "execution_time": "1379 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    amplitude = sqrt(1 / L)\n    amplitudes = [amplitude] * L + [0] * (2**n - L)\n    qc.initialize(amplitudes, range(n))\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0E9009986C74", "submission_order": 1, "result": "RE", "execution_time": "1793 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits to create superposition\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply controlled rotations to zero out states beyond L-1\n    for i in range(L, 2**n):\n        # Convert i to binary and apply a series of X gates to flip the states\n        binary_representation = format(i, f'0{n}b')\n        for qubit in range(n):\n            if binary_representation[qubit] == '1':\n                qc.x(qubit)\n        # Apply a controlled-NOT to flip the state back to |0> if the control qubit is |1>\n        qc.mct(list(range(n)), n)  # Multi-controlled Toffoli gate\n        for qubit in range(n):\n            if binary_representation[qubit] == '1':\n                qc.x(qubit)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0E9009986C74", "submission_order": 2, "result": "RE", "execution_time": "1794 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to the first L qubits\n    for i in range(L):\n        qc.h(i)  # Apply Hadamard to the first L qubits\n    \n    # Normalize the amplitudes\n    # The amplitude for each of the first L states will be 1/sqrt(L)\n    # This is already achieved by applying H gates to L qubits.\n    \n    # The remaining qubits (if any) should be set to |0>\n    # This is automatically the case since we initialized the circuit with |0>\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0E9009986C74", "submission_order": 3, "result": "AC", "execution_time": "2946 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\n\n    qc = QuantumCircuit(n)\n\n    # Number of qubits that must be in uniform superposition\n    k = 0 if L == 1 else math.ceil(math.log2(L))\n\n    # Apply Hadamard to the first k qubits (indices 0 … k-1)\n    for q in range(k):\n        qc.h(q)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 1, "result": "RE", "execution_time": "813 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    qc.ry(2*math.asin(math.sqrt(L-result/L)),m)\n    for num in range(m):\n        qc.h(num)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 2, "result": "RE", "execution_time": "1097 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    qc.ry(2*math.asin(math.sqrt((L-result)/L)),m)\n    for num in range(m):\n        qc.h(num)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 3, "result": "WA", "execution_time": "1039 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    qc.ry(2*math.asin(math.sqrt((L-result)/L)),m)\n    for num in range(m):\n        qc.h(num)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    for num in range(m):\n        qc.h(num)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 5, "result": "RE", "execution_time": "985 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L-:\n        result *= 2\n        m += 1\n    for num in range(m):\n        qc.h(num)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 6, "result": "RE", "execution_time": "973 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ni\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    for num in range(m):\n        qc.h(num)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 7, "result": "WA", "execution_time": "1151 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    for num in range(m):\n        qc.h(num)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 8, "result": "RE", "execution_time": "990 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n        qc.h(range(num))\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 9, "result": "RE", "execution_time": "794 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    qc.h(range(num))\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 10, "result": "RE", "execution_time": "911 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==1:\n        return qc\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    qc.h(range(num))\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F4753D93A8A", "submission_order": 11, "result": "RE", "execution_time": "1218 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==1:\n        return qc\n    m=0\n    result=1\n    while result*2 < L:\n        result *= 2\n        m += 1\n    qc.h(range(m))\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F5D577B76D8", "submission_order": 1, "result": "AC", "execution_time": "2915 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # for i in range(n):\n    #     qc.h(i)\n    # Write your code here:\n    if L == (1<<n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n    for i in reversed(range(n)):\n        if L&(1<<i) :\n            for j in range(i+1):\n                qc.h(j)\n            break\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F8119CF9439", "submission_order": 1, "result": "RE", "execution_time": "1111 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(math.ceil(math.log2(L))))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A0F8119CF9439", "submission_order": 2, "result": "AC", "execution_time": "1449 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(max(1, math.ceil(math.log2(L)))))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A11D7CA0B5392", "submission_order": 1, "result": "AC", "execution_time": "1337 ms", "memory": "92 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate, CXGate, MCPhaseGate, MCMT\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if 2 ** i >= L:\n            break\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A14C657C2F2EE", "submission_order": 1, "result": "RE", "execution_time": "1070 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ry(2 * math.acos(1 / math.sqrt(L)), 0)\n    qc.ch(0, 1)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A14C657C2F2EE", "submission_order": 2, "result": "RE", "execution_time": "902 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ry(2 * math.acos(1 / math.sqrt(L)), 0)\n    qc.ch(0, 1)\n\n    for i in range(n - 1, 0, -1):\n        qc.cx(i, i + 1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A14C657C2F2EE", "submission_order": 3, "result": "RE", "execution_time": "1274 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ry(2 * math.acos(1 / math.sqrt(L)), 0)\n    qc.ch(0, 1)\n\n    for i in range(n - 2):\n        qc.cx(i, i + 1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A14C657C2F2EE", "submission_order": 4, "result": "WA", "execution_time": "1047 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        return qc\n\n    qc.ry(2 * math.acos(1 / math.sqrt(L)), 0)\n    qc.ch(0, 1)\n\n    for i in range(n - 2):\n        qc.cx(i, i + 1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A14C657C2F2EE", "submission_order": 5, "result": "WA", "execution_time": "1234 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        return qc\n\n    qc.ry(2 * math.acos(1 / math.sqrt(L)), 0)\n    qc.ch(0, 1)\n\n    # qc.cx(1, 2)\n    # qc.cx(0, 1)  # n = 3, L = 3\n\n    for i in range(n - 2, 0, -1):\n        qc.cx(0, i)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1A8D43A345C7", "submission_order": 1, "result": "WA", "execution_time": "1043 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1A8D43A345C7", "submission_order": 2, "result": "WA", "execution_time": "1016 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.cz(i,i+1)\n        qc.h(i+1)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1A8D43A345C7", "submission_order": 3, "result": "RE", "execution_time": "831 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.cz(i,i+1)\n        qc.h(i+1)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1A8D43A345C7", "submission_order": 4, "result": "WA", "execution_time": "1132 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.cz(i,i+1)\n        qc.h(i+1)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble, execute\nfrom qiskit.visualization import plot_histogram\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef oracle(n: int, L: int) -> QuantumCircuit:\n    \"\"\" オラクル関数 \"\"\"\n    qc = QuantumCircuit(n)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = []\n        for j in range(i+1, n):\n            lst.append(j)\n\n        if len(lst) == 0:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n\ndef diffusion_operator(n):\n    \"\"\" 拡散操作関数 \"\"\"\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n\ndef solve(n, L):\n    \"\"\" グローバーのアルゴリズムを使って特定のビット列 L を見つけ出す関数 \"\"\"\n    qc = QuantumCircuit(n, n)\n\n    # 初期化\n    for i in range(n):\n        qc.h(i)\n\n    # 繰り返し回数\n    iterations = int(math.sqrt((2**n)))\n\n    for _ in range(iterations):\n        # オラクルの適用\n        qc.append(oracle(n, L), range(n))\n        \n        # 拡散操作の適用\n        qc.append(diffusion_operator(n), range(n))\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble, execute\n#from qiskit.visualization import plot_histogram\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef oracle(n: int, L: int) -> QuantumCircuit:\n    \"\"\" オラクル関数 \"\"\"\n    qc = QuantumCircuit(n)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = []\n        for j in range(i+1, n):\n            lst.append(j)\n\n        if len(lst) == 0:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n\ndef diffusion_operator(n):\n    \"\"\" 拡散操作関数 \"\"\"\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n\ndef solve(n, L):\n    \"\"\" グローバーのアルゴリズムを使って特定のビット列 L を見つけ出す関数 \"\"\"\n    qc = QuantumCircuit(n, n)\n\n    # 初期化\n    for i in range(n):\n        qc.h(i)\n\n    # 繰り返し回数\n    iterations = int(math.sqrt((2**n)))\n\n    for _ in range(iterations):\n        # オラクルの適用\n        qc.append(oracle(n, L), range(n))\n        \n        # 拡散操作の適用\n        qc.append(diffusion_operator(n), range(n))\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 3, "result": "RE", "execution_time": "947 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef oracle(n: int, L: int) -> QuantumCircuit:\n    \"\"\" オラクル関数 \"\"\"\n    qc = QuantumCircuit(n)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = []\n        for j in range(i+1, n):\n            lst.append(j)\n\n        if len(lst) == 0:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n\ndef diffusion_operator(n):\n    \"\"\" 拡散操作関数 \"\"\"\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n\ndef solve(n, L):\n    \"\"\" グローバーのアルゴリズムを使って特定のビット列 L を見つけ出す関数 \"\"\"\n    qc = QuantumCircuit(n, n)\n\n    # 初期化\n    for i in range(n):\n        qc.h(i)\n\n    # 繰り返し回数\n    iterations = int(math.sqrt((2**n)))\n\n    for _ in range(iterations):\n        # オラクルの適用\n        qc.append(oracle(n, L), range(n))\n        \n        # 拡散操作の適用\n        qc.append(diffusion_operator(n), range(n))\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 4, "result": "RE", "execution_time": "1112 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef oracle(n: int, L: int) -> QuantumCircuit:\n    \"\"\" オラクル関数 \"\"\"\n    qc = QuantumCircuit(n)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = []\n        for j in range(i+1, n):\n            lst.append(j)\n\n        if len(lst) == 0:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n\ndef diffusion_operator(n):\n    \"\"\" 拡散操作関数 \"\"\"\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n\ndef solve(n, L):\n    \"\"\" グローバーのアルゴリズムを使って特定のビット列 L を見つけ出す関数 \"\"\"\n    qc = QuantumCircuit(n, n)\n\n    # 初期化\n    for i in range(n):\n        qc.h(i)\n\n    # 繰り返し回数\n    iterations = int(math.sqrt((2**n)))\n\n    for _ in range(iterations):\n        # オラクルの適用\n        qc.append(oracle(n, L), range(n))\n        \n        # 拡散操作の適用\n        qc.append(diffusion_operator(n), range(n))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 5, "result": "RE", "execution_time": "1252 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef oracle(qc,n, L):\n    \"\"\" オラクル関数 \"\"\"\n    #qc = QuantumCircuit(n)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = []\n        for j in range(i+1, n):\n            lst.append(j)\n\n        if len(lst) == 0:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n\ndef diffusion_operator(qc,n):\n    \"\"\" 拡散操作関数 \"\"\"\n    #qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n\ndef solve(n:int, L:int):\n    \"\"\" グローバーのアルゴリズムを使って特定のビット列 L を見つけ出す関数 \"\"\"\n    qc = QuantumCircuit(n)\n\n    # 初期化\n    for i in range(n):\n        qc.h(i)\n\n    # 繰り返し回数\n    iterations = int(math.sqrt((2**n)))\n\n    for _ in range(iterations):\n        # オラクルの適用\n        #qc.append(oracle(n, L), range(n))\n        oracle(qc,n, L)\n\n        \n        # 拡散操作の適用\n        #qc.append(diffusion_operator(n), range(n))\n        diffusion_operator(qc,n)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 6, "result": "RE", "execution_time": "1201 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef oracle(qc,n, L):\n    \"\"\" オラクル関数 \"\"\"\n    #qc = QuantumCircuit(n)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = []\n        for j in range(i+1, n):\n            lst.append(j)\n\n        if len(lst) == 0:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n\ndef diffusion_operator(qc,n):\n    \"\"\" 拡散操作関数 \"\"\"\n    #qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n\ndef solve(n:int, L:int):\n    \"\"\" グローバーのアルゴリズムを使って特定のビット列 L を見つけ出す関数 \"\"\"\n    qc = QuantumCircuit(n)\n\n    # 初期化\n    for i in range(n):\n        qc.h(i)\n\n    # 繰り返し回数\n    iterations = int(math.sqrt((2**n)/L))\n\n    for _ in range(iterations):\n        # オラクルの適用\n        #qc.append(oracle(n, L), range(n))\n        oracle(qc,n, L)\n\n        \n        # 拡散操作の適用\n        #qc.append(diffusion_operator(n), range(n))\n        diffusion_operator(qc,n)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 7, "result": "RE", "execution_time": "1302 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef oracle(qc,n, L):\n    \"\"\" オラクル関数 \"\"\"\n    #qc = QuantumCircuit(n)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = []\n        for j in range(i+1, n):\n            lst.append(j)\n\n        if len(lst) == 0:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n\ndef diffusion_operator(qc,n):\n    \"\"\" 拡散操作関数 \"\"\"\n    #qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n\ndef solve(n:int, L:int):\n    \"\"\" グローバーのアルゴリズムを使って特定のビット列 L を見つけ出す関数 \"\"\"\n    qc = QuantumCircuit(n)\n\n    # 初期化\n    for i in range(n):\n        qc.h(i)\n\n    # 繰り返し回数\n    iterations = int(math.sqrt((2**n)/(L+1)))\n\n    for _ in range(iterations):\n        # オラクルの適用\n        #qc.append(oracle(n, L), range(n))\n        oracle(qc,n, L)\n\n        \n        # 拡散操作の適用\n        #qc.append(diffusion_operator(n), range(n))\n        diffusion_operator(qc,n)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 8, "result": "RE", "execution_time": "1843 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport math\n\ndef oracle(qc,n, L):\n    \"\"\" オラクル関数 \"\"\"\n    #qc = QuantumCircuit(n)\n    ato = []\n    for i in range(n-1,-1,-1):\n        lst = []\n        for j in range(i+1, n):\n            lst.append(j)\n\n        if len(lst) == 0:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n        else:\n            if (L >> i) & 1:\n                qc.x(i)\n                qc.append(MCPhaseGate(math.pi, len(lst)), lst + [i])\n                qc.x(i)\n            else:\n                qc.x(i)\n                ato.append(i)\n\n    for i in ato:\n        qc.x(i)\n    return qc\n\ndef diffusion_operator(qc,n):\n    \"\"\" 拡散操作関数 \"\"\"\n    #qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n\ndef solve(n:int, L:int):\n    \"\"\" グローバーのアルゴリズムを使って特定のビット列 L を見つけ出す関数 \"\"\"\n    qc = QuantumCircuit(n)\n\n    # 初期化\n    for i in range(n):\n        qc.h(i)\n\n    # 繰り返し回数\n    iterations = int(math.sqrt((2**n)/(0+1)))\n\n    for _ in range(iterations):\n        # オラクルの適用\n        #qc.append(oracle(n, L), range(n))\n        oracle(qc,n, L)\n\n        \n        # 拡散操作の適用\n        #qc.append(diffusion_operator(n), range(n))\n        diffusion_operator(qc,n)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 9, "result": "RE", "execution_time": "1016 ms", "memory": "88 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nimport math\nfrom qiskit import QuantumCircuit\n\n\ndef append_cry(qc, angle, ctrl_lst, tgt):\n    if ctrl_lst:\n        # 制御量子ビットがある場合、制御RYゲートを追加\n        qc.append(RYGate(angle).control(len(ctrl_lst)), ctrl_lst + [tgt])\n    else:\n        # 制御量子ビットがない場合、通常のRYゲートを追加\n        qc.ry(angle, tgt)\n\ndef append_ch(qc, ctrl_lst, tgt):\n    if ctrl_lst:\n        # 制御量子ビットがある場合、制御Hゲートを追加\n        qc.append(HGate().control(len(ctrl_lst)), ctrl_lst + [tgt])\n    else:\n        # 制御量子ビットがない場合、通常のHゲートを追加\n        qc.h(tgt)\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    dq = [(0,n,L)]\n    while dq:\n        x,m,l = dq.pop(0)\n        #print(x,m,l)\n        if l == 0 or m == 0:\n            continue\n        \n        if l == 2**m:\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            for j in range(m):\n                append_ch(qc,[_ for _ in range(m,n)],j)\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            #qc.barrier()\n            continue\n\n\n        left = min(2**(m-1),l)\n        right = l-left\n\n        if left != l:\n            # 処理2\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            append_cry(qc, 2*math.acos((left/l)**0.5),[_ for _ in range(m,n)],m-1)\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            #qc.barrier()\n        # 追加2\n        dq.append((x,m-1,left))\n        dq.append((x+2**(m-1),m-1,right))\n'''"}
{"problem": "QPC001_C1", "user": "A1CF3A7FE862D", "submission_order": 10, "result": "AC", "execution_time": "2891 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nimport math\nfrom qiskit import QuantumCircuit\n\n\ndef append_cry(qc, angle, ctrl_lst, tgt):\n    if ctrl_lst:\n        # 制御量子ビットがある場合、制御RYゲートを追加\n        qc.append(RYGate(angle).control(len(ctrl_lst)), ctrl_lst + [tgt])\n    else:\n        # 制御量子ビットがない場合、通常のRYゲートを追加\n        qc.ry(angle, tgt)\n\ndef append_ch(qc, ctrl_lst, tgt):\n    if ctrl_lst:\n        # 制御量子ビットがある場合、制御Hゲートを追加\n        qc.append(HGate().control(len(ctrl_lst)), ctrl_lst + [tgt])\n    else:\n        # 制御量子ビットがない場合、通常のHゲートを追加\n        qc.h(tgt)\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    dq = [(0,n,L)]\n    while dq:\n        x,m,l = dq.pop(0)\n        #print(x,m,l)\n        if l == 0 or m == 0:\n            continue\n        \n        if l == 2**m:\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            for j in range(m):\n                append_ch(qc,[_ for _ in range(m,n)],j)\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            #qc.barrier()\n            continue\n\n\n        left = min(2**(m-1),l)\n        right = l-left\n\n        if left != l:\n            # 処理2\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            append_cry(qc, 2*math.acos((left/l)**0.5),[_ for _ in range(m,n)],m-1)\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            #qc.barrier()\n        # 追加2\n        dq.append((x,m-1,left))\n        dq.append((x+2**(m-1),m-1,right))\n        \n\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A1E68539863FB", "submission_order": 1, "result": "AC", "execution_time": "1508 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve_rec(qc: QuantumCircuit, n: int, bit: int, L: int) -> None:\n    if bit < 0:\n        return\n    if L < (1<<bit):\n        qc.x(bit)\n        solve_rec(qc, n, bit-1, L)\n        qc.x(bit)\n    else:\n        qc.r(math.pi/2, 0, bit)\n        qc.mcp(-2*math.acos(math.sqrt((1<<bit)/L)), list(range(bit+1,n)), bit)\n        qc.r(-math.pi/2, 0, bit)\n        qc.x(bit)\n        for i in range(bit):\n            qc.r(math.pi/2, 0, i)\n            qc.mcp(math.pi/2, list(range(bit,n)), i)\n            qc.r(-math.pi/2, 0, i)\n        qc.x(bit)\n        solve_rec(qc, n, bit-1, L-(1<<bit))\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1 and L == 2:\n        qc.h(0)\n    if n == 1:\n        return qc\n    if L < (1<<(n-1)):\n        qc.x(n-1)\n        solve_rec(qc, n, n-2, L)\n        qc.x(n-1)\n    else:\n        qc.r(2*math.acos(math.sqrt((1<<(n-1))/L)), math.pi/2, n-1)\n        qc.x(n-1)\n        for i in range(n-1):\n            qc.ch(n-1, i)\n        qc.x(n-1)\n        solve_rec(qc, n, n-2, L-(1<<(n-1)))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A210272EB446F", "submission_order": 1, "result": "AC", "execution_time": "2552 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, asin, sqrt, floor\n\n\ndef oracle(qc: QuantumCircuit, n: int, L: int) -> QuantumCircuit:\n    K = L - 1\n\n    xgates = []\n    for i in range(n - 1, -1, -1):\n        if (K >> i) & 1:\n            continue\n\n        if i < n - 1:\n            qc.mcp(pi, list(range(i + 1, n)), i)\n        else:\n            qc.z(i)\n\n        xgates.append(i)\n        qc.x(i)\n\n    for i in xgates:\n        qc.x(i)\n\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    theta = asin(sqrt(L / (1 << n)))\n    r = floor(pi / (4 * theta))\n    # print(theta, r)\n\n    for _ in range(r):\n        oracle(qc, n, L)\n\n        for i in range(n):\n            qc.h(i)\n            qc.x(i)\n\n        if n > 1:\n            qc.mcp(pi, list(range(n - 1)), n - 1)\n        else:\n            qc.z(n - 1)\n\n        for i in range(n):\n            qc.x(i)\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A22E8FF31DD25", "submission_order": 1, "result": "AC", "execution_time": "1604 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i = 0\n    while (1 << i) < L:\n        qc.h(i)\n        i += 1\n    \n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A26CD432DBFF1", "submission_order": 1, "result": "RE", "execution_time": "1160 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i=0\n    while 2**i <= L:\n        qc.h(i)\n        i+=1\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A26CD432DBFF1", "submission_order": 2, "result": "AC", "execution_time": "2391 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if 2**i <= L:\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A285CD8FDE58D", "submission_order": 1, "result": "TOE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    k=0\n    while L>1:\n        k++\n        L=L/2\n    for i in range(k):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A2B62D01D1154", "submission_order": 1, "result": "AC", "execution_time": "2592 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i = 0\n    while 2 ** i < L:\n      qc.h(i)\n      i += 1\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A31322EC432EE", "submission_order": 1, "result": "AC", "execution_time": "2561 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, HGate, RYGate\nfrom math import sqrt, acos, pi\n\ndef append_control_gate(qc: QuantumCircuit, gate, target_qubit: int, ctrl_state: int, controlled_qubits)->QuantumCircuit:\n\tif len(controlled_qubits) == 0:\n\t\tqc.append(gate, [target_qubit])\n\telse:\n\t\tqc.append(gate.control(len(controlled_qubits), ctrl_state = ctrl_state), controlled_qubits + [target_qubit])\n\treturn qc\n\ndef solve(n: int, L: int)->QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif L == (1 << n):\n\t\tfor i in range(n):\n\t\t\tqc.h(i)\n\t\treturn qc\n\tmask = (1 << n) - 1\n\tctrl_state = 0\n\tcontrolled_qubits = []\n\tfor bit in range(n - 1, -1, -1):\n\t\tif L >> bit & 1:\n\t\t\tleft, right = 1 << bit, L - (1 << bit)\n\t\t\ttheta = acos(sqrt(left) / sqrt(left + right)) * 2\n\t\t\tappend_control_gate(qc, RYGate(theta), bit, ctrl_state, controlled_qubits)\n\t\t\tfor bit_next in range(bit - 1, -1, -1):\n\t\t\t\tappend_control_gate(qc, HGate(), bit_next, ctrl_state, controlled_qubits + [bit])\n\t\t\tL ^= 1 << bit\n\t\t\tctrl_state |= 1 << len(controlled_qubits)\n\t\tcontrolled_qubits += [bit]\n\treturn qc\n'''"}
{"problem": "QPC001_C1", "user": "A3675FD3AC86E", "submission_order": 1, "result": "RE", "execution_time": "837 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.acos(math.sqrt(0.5))\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        for j in range(i+1, n):\n            qc.cz(i, j)\n    qc.u1(theta, n-1)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A3675FD3AC86E", "submission_order": 2, "result": "WA", "execution_time": "983 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.acos(math.sqrt(0.5))\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        for j in range(i+1, n):\n            qc.cz(i, j)\n    qc.p(theta, n-1)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A441909F96BBB", "submission_order": 1, "result": "AC", "execution_time": "2343 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m = math.ceil(math.log2(L))\n    for i in range(m):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A46C24B77CC3E", "submission_order": 1, "result": "RE", "execution_time": "993 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\tdef lessthan(qc: QuantumCircuit, n: int, L: int):\n        def xmap(m: int, size: int) -> list[int]:\n              a = []\n              idx = 0\n              while m:\n                  if m % 2:\n                      a.append(idx)\n                  idx += 1\n                  m //= 2\n              return [i for i in range(size) if i not in a]\n        for i in range(L, 2**n):\n            a = xmap(i, n)\n            if a:\n                qc.x(a)\n            if n > 1:\n                qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n            else:\n                qc.z(0)\n            if a:\n                qc.x(a)\n\n    def zmark(qc,n):\n        for i in range(n):\n            qc.h(i); qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n        for i in range(n):\n            qc.x(i); qc.h(i)\n\n    for i in range(n):\n        qc.h(i)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A46C24B77CC3E", "submission_order": 2, "result": "RE", "execution_time": "904 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\tdef lessthan(qc: QuantumCircuit, n: int, L: int):\n        def xmap(m: int, size: int) -> list[int]:\n              a = []\n              idx = 0\n              while m:\n                  if m % 2:\n                      a.append(idx)\n                  idx += 1\n                  m //= 2\n              return [i for i in range(size) if i not in a]\n        for i in range(L, 2**n):\n            a = xmap(i, n)\n            if a:\n                qc.x(a)\n            if n > 1:\n                qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n            else:\n                qc.z(0)\n            if a:\n                qc.x(a)\n\n    def zmark(qc,n):\n        for i in range(n):\n            qc.h(i); qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n        for i in range(n):\n            qc.x(i); qc.h(i)\n\n    for i in range(n):\n        qc.h(i)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A46C24B77CC3E", "submission_order": 3, "result": "WA", "execution_time": "1138 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def lessthan(qc: QuantumCircuit, n: int, L: int):\n        def xmap(m: int, size: int) -> list[int]:\n              a = []\n              idx = 0\n              while m:\n                  if m % 2:\n                      a.append(idx)\n                  idx += 1\n                  m //= 2\n              return [i for i in range(size) if i not in a]\n        for i in range(L, 2**n):\n            a = xmap(i, n)\n            if a:\n                qc.x(a)\n            if n > 1:\n                qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n            else:\n                qc.z(0)\n            if a:\n                qc.x(a)\n\n    def zmark(qc,n):\n        for i in range(n):\n            qc.h(i); qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n        for i in range(n):\n            qc.x(i); qc.h(i)\n\n    for i in range(n):\n        qc.h(i)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A46C24B77CC3E", "submission_order": 4, "result": "WA", "execution_time": "1120 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def lessthan(qc: QuantumCircuit, n: int, L: int):\n        def xmap(m: int, size: int) -> list[int]:\n              a = []\n              idx = 0\n              while m:\n                  if m % 2:\n                      a.append(idx)\n                  idx += 1\n                  m //= 2\n              return [i for i in range(size) if i not in a]\n        for i in range(L, 2**n):\n            a = xmap(i, n)\n            if a:\n                qc.x(a)\n            if n > 1:\n                qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n            else:\n                qc.z(0)\n            if a:\n                qc.x(a)\n\n    def zmark(qc,n):\n        for i in range(n):\n            qc.h(i); qc.x(i)\n        if n==1:\n            qc.z(0)\n        else:\n            qc.h(0); qc.mcx(list(range(1, n)), 0); qc.h(0)\n        for i in range(n):\n            qc.x(i); qc.h(i)\n\n    for i in range(n):\n        qc.h(i)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)\n    lessthan(qc, n, L); zmark(qc, n)    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A46C24B77CC3E", "submission_order": 5, "result": "AC", "execution_time": "3000 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def xmap(m: int) -> list[int]:\n        a = []\n        idx = 0\n        while m:\n            if m % 2:\n                a.append(idx)\n            idx += 1\n            m //= 2\n        return a\n    if L == 0:\n        return qc\n    regs = list(range(0, min(n, xmap(L)[-1]+1)))\n    if regs:\n        qc.h(regs)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4809422A3E4B", "submission_order": 1, "result": "RE", "execution_time": "832 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    i = 0\n\n    while (l+1 > 2**i):\n        i += 1\n\n    for j in range(i):\n        qc.h(j)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4809422A3E4B", "submission_order": 2, "result": "RE", "execution_time": "1193 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    i = 0\n\n    while (L+1 > 2**i):\n        i += 1\n\n    for j in range(i):\n        qc.h(j)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4809422A3E4B", "submission_order": 3, "result": "AC", "execution_time": "2251 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc = QuantumCircuit(n)\n\n    i = 0\n\n    while (L > 2**i):\n        i += 1\n\n    for j in range(i):\n        qc.h(j)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4964A8FAE6C2", "submission_order": 1, "result": "AC", "execution_time": "2557 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_keta = 1\n    for i in range(n):\n        if 2**i <= L:\n            L_keta = i+1\n\n    for i in range(L_keta):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4A7E21F2F230", "submission_order": 1, "result": "RE", "execution_time": "1139 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(math.ceil(math.log2(L))))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4A7E21F2F230", "submission_order": 2, "result": "RE", "execution_time": "1155 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n    qc.h(range(math.ceil(math.log2(L))))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4A7E21F2F230", "submission_order": 3, "result": "RE", "execution_time": "758 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n    m=math.ceil(math.log2(L))\n    qc.h(range(m))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4A7E21F2F230", "submission_order": 4, "result": "AC", "execution_time": "1776 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==1:\n        return qc\n        \n    import math\n    m=math.ceil(math.log2(L))\n    qc.h(range(m))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4AA855286D55", "submission_order": 1, "result": "AC", "execution_time": "1479 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1: return qc\n    k = 1\n    while 1 << k < L: k += 1\n    for i in range(k): qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A4F1301407711", "submission_order": 1, "result": "AC", "execution_time": "1799 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if L > (1 << i):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A52D7E6ECC137", "submission_order": 1, "result": "RE", "execution_time": "1134 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    eff_n = int(math.log2(L)) + 1\n    qc.h(0)\n    for i in range(eff_n - 1):\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A52D7E6ECC137", "submission_order": 2, "result": "RE", "execution_time": "1053 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    eff_n = int(math.log2(L - 1)) + 1\n    print(eff_n)\n    qc.h(0)\n    for i in range(eff_n - 1):\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A52D7E6ECC137", "submission_order": 3, "result": "RE", "execution_time": "985 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    eff_n = int(math.log2(L - 1)) + 1\n    for i in range(eff_n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A52D7E6ECC137", "submission_order": 4, "result": "AC", "execution_time": "1732 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    eff_n = int(math.log2(L - 1)) + 1 if L > 1 else 0\n    for i in range(eff_n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5679677B5C6A", "submission_order": 1, "result": "RE", "execution_time": "1616 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L.bit_length()):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5679677B5C6A", "submission_order": 2, "result": "RE", "execution_time": "1399 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(str(L).bit_length()):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5679677B5C6A", "submission_order": 3, "result": "AC", "execution_time": "1557 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(L.bit_length()-int(2**n==L)):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5686D4D93196", "submission_order": 1, "result": "RE", "execution_time": "954 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=L-1\n    k=0\n    while l>0:\n        for i in range(n-1-k,-1,-1):\n            if 1<<i > l:\n                continue\n            if 1<<i <=l and 1<<(i+1)>l:\n                print(1<<(i))\n                qc.u(-math.acos(math.sqrt((1<<i))/math.sqrt(l+1))*2,math.pi,0,i)\n                qc.x(i)\n                c3h_gate = HGate().control(1)\n                for j in range(0,i):\n                    qc.append(c3h_gate,[i,j])\n                qc.x(i)\n\n                k+=1\n                l=l-(1<<i) # 最上位ビット削除\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5686D4D93196", "submission_order": 2, "result": "RE", "execution_time": "1439 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import HGate, U3Gate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l=L-1\n    k=0\n    while l>0:\n        maxi=0\n        for i in range(n-1-k,-1,-1):\n            if 1<<i > l:\n                continue\n            if 1<<i <=l and 1<<(i+1)>l:\n                maxi=max(maxi,i)\n                print(1<<(i))\n                # if i>0:\n                l2=L-1\n                for k1 in range(n-1,i,-1):\n                    if not (1<<k1)&l2:\n                        qc.x(k1)\n                clist=list(range(n-1,i,-1))+[i]\n                cu3_gate = U3Gate(-math.acos(math.sqrt((1<<i))/math.sqrt(l+1))*2,math.pi,0).control(len(clist)-1)\n                print(clist)\n                qc.append(cu3_gate,clist)\n\n                l2=L-1\n                for k1 in range(n-1,i,-1):\n                    if not (1<<k1)&l2:\n                        qc.x(k1)\n\n                qc.x(i)\n                for j in range(n-1,maxi,-1):\n                    qc.x(j)\n                for j in range(0,i):\n                    clist=list(range(n-1,i-1,-1))+[j]\n\n                    c3h_gate = HGate().control(len(clist)-1)\n                    print(clist)\n                    qc.append(c3h_gate,clist)\n                qc.x(i)\n                for j in range(n-1,maxi,-1):\n                    qc.x(j)\n\n                k+=1\n                l=l-(1<<i) # 最上位ビット削除\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A586E2A50EDE7", "submission_order": 1, "result": "RE", "execution_time": "2880 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import sqrt, log2, ceil\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Determine the required number of qubits\n    num_states = min(L, 2**n)  # Ensure L does not exceed the total number of states\n    \n    # Apply Hadamard gates on a subset of qubits to create a superposition\n    num_qubits_needed = ceil(log2(num_states))\n    for i in range(num_qubits_needed):\n        qc.h(i)\n    \n    # Use a barrier for visualization (optional)\n    qc.barrier()\n    \n    # If L is not a power of 2, we need to adjust the probability amplitudes\n    if num_states != 2**num_qubits_needed:\n        probability_threshold = num_states / 2**num_qubits_needed\n        qc.ry(2 * sqrt(probability_threshold), num_qubits_needed - 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A586E2A50EDE7", "submission_order": 2, "result": "UGE", "execution_time": "1559 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # The total Hilbert space has dimension 2^n.\n    dim = 2 ** n\n    \n    # Create a state vector of length 2^n.\n    # For i in 0 to L-1, set the amplitude to 1/sqrt(L), and leave all other amplitudes as 0.\n    state = [0] * dim\n    amplitude = 1 / math.sqrt(L)\n    for i in range(L):\n        state[i] = amplitude\n        \n    # Use Qiskit's initialize() method.\n    # Passing list(range(n)) makes sure the state vector is interpreted in little-endian order.\n    qc.initialize(state, list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A586E2A50EDE7", "submission_order": 3, "result": "TLE", "execution_time": "3000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Given a k–bit prefix (interpreted in big–endian order),\n    # count how many numbers in {0,1,...,L-1} have that prefix.\n    def count(prefix: int, k: int, L: int, n: int) -> int:\n        # The k–bit prefix p (an integer in 0,...,2^k-1)\n        # corresponds to all numbers in the interval:\n        #    [ p * 2^(n-k),  (p+1)*2^(n-k) - 1 ]\n        low = prefix * (2 ** (n - k))\n        # high = (prefix+1)*2^(n-k) - 1   (not needed explicitly)\n        if L <= low:\n            return 0\n        return min(2 ** (n - k), L - low)\n    \n    # Recursively “build” the uniformly controlled rotations.\n    # Here, k is the number of bits already fixed.\n    # (We work in “logical” qubit order – that is, logical qubit 0 is the most–significant bit.\n    # Later we note that physical qubit (n-1) will play the role of logical qubit 0,\n    # physical qubit (n-2) that of logical qubit 1, etc. This exactly produces little–endian encoding.)\n    def prepare(prefix: int, k: int):\n        if k == n:\n            return  # all bits fixed\n        f_prefix = count(prefix, k, L, n)\n        if f_prefix == 0:\n            return  # no amplitude flows down this branch\n        # Compute counts for the two branches:\n        f0 = count(prefix * 2, k + 1, L, n)\n        f1 = count(prefix * 2 + 1, k + 1, L, n)\n        # The desired rotation should “split” the amplitude so that the |0⟩ branch gets weight f0/f_prefix.\n        # In other words, choose theta so that:\n        #   cos(theta/2) = sqrt(f0/f_prefix)\n        theta = 2 * math.acos(math.sqrt(f0 / f_prefix))\n        # The target qubit for level k is logical qubit k, which we now map to physical qubit (n-1-k)\n        target = n - 1 - k\n        if k == 0:\n            # No control needed on the very first rotation.\n            qc.ry(theta, target)\n        else:\n            # Controls come from the previously fixed (logical) qubits.\n            # (They are mapped to physical qubits: logical j -> physical (n-1-j).)\n            controls = [n - 1 - j for j in range(k)]\n            # Because Qiskit’s controlled–rotation (cry/mcry) gates control on |1⟩,\n            # we “flip” any control qubit whose bit in our prefix is 0.\n            for j in range(k):\n                bit = (prefix >> (k - 1 - j)) & 1  # extract the jth bit (with j=0 = most–significant)\n                if bit == 0:\n                    qc.x(n - 1 - j)\n            if k == 1:\n                qc.cry(theta, controls[0], target)\n            else:\n                qc.mcry(theta, controls, target, None, mode='noancilla')\n            for j in range(k):\n                bit = (prefix >> (k - 1 - j)) & 1\n                if bit == 0:\n                    qc.x(n - 1 - j)\n        # Recurse to “prepare” the next bits in both branches.\n        prepare(prefix * 2, k + 1)\n        prepare(prefix * 2 + 1, k + 1)\n    \n    # Begin with an empty prefix.\n    prepare(0, 0)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A586E2A50EDE7", "submission_order": 4, "result": "AC", "execution_time": "2938 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # For L == 1, the initial state |0...0> already meets the requirement.\n    if L == 1:\n        return qc\n\n    # Determine the smallest k such that 2^k >= L.\n    k = math.ceil(math.log2(L))\n    \n    # Apply Hadamard to the first k qubits.\n    qc.h(range(k))\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A59B44D998810", "submission_order": 1, "result": "RE", "execution_time": "1090 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(int.bit_length(L)):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A59B44D998810", "submission_order": 2, "result": "AC", "execution_time": "2319 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(int.bit_length(L-1)):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A59BE1905D54A", "submission_order": 1, "result": "WA", "execution_time": "2129 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \ndef add_rule(qc: QuantumCircuit, n: int, suffix: list[int], Lpre: int) -> None:\n    k = len(suffix)\n    split_idx = n - k - 1\n\n    #print(f\"Lpre={Lpre}, split_idx={split_idx}\")\n    num = 1 << split_idx\n    denom = Lpre\n    #print(f\"{num}/{denom}\")\n    theta = math.acos(math.sqrt(num/denom)) * 2\n    if k > 0:\n        idx = n - 1\n        for bit in suffix:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n        #print(\"ry\", k, range(split_idx + 1, n))\n        qc.append(RYGate(theta).control(k), list(range(split_idx + 1, n)) + [split_idx])\n        idx = n - 1\n        for bit in suffix:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n    else:\n        qc.ry(theta, n - 1)\n\n    #print(suffix)\n    for i in range(0, split_idx):\n        idx = n - 1\n        for bit in suffix + [0]:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n\n        size = k + 1\n        qubits = list(range(split_idx, n)) + [i]\n        #print(size, qubits)\n        qc.append(HGate().control(size), qubits)\n\n        idx = n - 1\n        for bit in suffix + [0]:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if L == (1 << n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n\n    cnt = 0\n    suffix = []\n    Lpre = L\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            add_rule(qc, n, suffix, Lpre)\n            if cnt == 1:\n                break\n            Lpre -= (1 << i)\n            suffix.append(1)\n        else:\n            suffix.append(0)\n        \n        cnt += 1\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A59BE1905D54A", "submission_order": 2, "result": "AC", "execution_time": "2839 ms", "memory": "166 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \ndef add_rule(qc: QuantumCircuit, n: int, suffix: list[int], Lpre: int) -> None:\n    k = len(suffix)\n    split_idx = n - k - 1\n\n    #print(f\"Lpre={Lpre}, split_idx={split_idx}\")\n    num = 1 << split_idx\n    denom = Lpre\n    #print(f\"{num}/{denom}\")\n    theta = math.acos(math.sqrt(num/denom)) * 2\n    if k > 0:\n        idx = n - 1\n        for bit in suffix:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n        #print(\"ry\", k, range(split_idx + 1, n))\n        qc.append(RYGate(theta).control(k), list(range(split_idx + 1, n)) + [split_idx])\n        idx = n - 1\n        for bit in suffix:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n    else:\n        qc.ry(theta, n - 1)\n\n    #print(suffix)\n    for i in range(0, split_idx):\n        idx = n - 1\n        for bit in suffix + [0]:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n\n        size = k + 1\n        qubits = list(range(split_idx, n)) + [i]\n        #print(size, qubits)\n        qc.append(HGate().control(size), qubits)\n\n        idx = n - 1\n        for bit in suffix + [0]:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if L == (1 << n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n\n    cnt = 0\n    suffix = []\n    Lpre = L\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            add_rule(qc, n, suffix, Lpre)\n            Lpre -= (1 << i)\n            suffix.append(1)\n        else:\n            suffix.append(0)\n        \n        cnt += 1\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5B8DFCC2E275", "submission_order": 1, "result": "RE", "execution_time": "947 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n + 1):\n        if L <= 2 ** i:\n            last = i\n            break\n    \n    prob_amp = math.sqrt(2 ** (last - 1) / L)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.ry(rot_ang, last)\n    for i in range(last):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5B8DFCC2E275", "submission_order": 2, "result": "RE", "execution_time": "863 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n + 1):\n        if L <= 2 ** i:\n            last = i\n            break\n    \n    prob_amp = math.sqrt((L - 2 ** (last - 1)) / L)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.ry(rot_ang, last)\n    for i in range(last):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5B8DFCC2E275", "submission_order": 3, "result": "RE", "execution_time": "972 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n + 1):\n        if L <= 2 ** i:\n            last = i\n            break\n    \n    prob_amp = math.sqrt((L -2 ** (last - 1)) / L)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.ry(rot_ang, last)\n    for i in range(last):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5B8DFCC2E275", "submission_order": 4, "result": "WA", "execution_time": "1029 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n + 1):\n        if L <= 2 ** i:\n            last = i\n            break\n    \n    prob_amp = math.sqrt((L -2 ** (last - 1)) / L)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.ry(rot_ang, last - 1)\n    for i in range(last - 1):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5BA3B5EE1491", "submission_order": 1, "result": "RE", "execution_time": "1824 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    bits = 0\n    while L:\n        L >>= 1\n        bits += 1\n\n    for i in range(bits):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5BA3B5EE1491", "submission_order": 2, "result": "AC", "execution_time": "2537 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    L -= 1\n    \n    bits = 0\n    while L:\n        L >>= 1\n        bits += 1\n\n    for i in range(bits):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5DC4DE6A934C", "submission_order": 1, "result": "WA", "execution_time": "1902 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = 0\n    for i in range(n):\n        if L <= (1<<i):\n            a = i\n    for i in range(a):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5DC4DE6A934C", "submission_order": 2, "result": "WA", "execution_time": "1731 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = 0\n    for i in range(n):\n        if L <= (1<<i):\n            a = i+1\n            break\n    for i in range(a):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5DC4DE6A934C", "submission_order": 3, "result": "WA", "execution_time": "2021 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = 0\n    for i in range(n):\n        if L <= (1<<i):\n            a = i\n            break\n    for i in range(a):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5DC4DE6A934C", "submission_order": 4, "result": "WA", "execution_time": "1660 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = 0\n    for i in range(n):\n        if L-1 <= (1<<i):\n            a = i+1\n            break\n    for i in range(a):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5DC4DE6A934C", "submission_order": 5, "result": "AC", "execution_time": "2575 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = 0\n    for i in range(n+1):\n        if L <= (1<<i):\n            a = i\n            break\n    for i in range(a):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5F2AFBDD89E6", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "145 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nimport qiskit.circuit.library as qis\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    bits = []\n    ones = []\n    for i in range(n-1, -1, -1):\n        if L & (1<<i) != 0:\n            bits += [(i, len(ones), 1)]\n            ones += [i]\n        else:\n            bits += [(i, len(ones), 0)]\n\n    for target, up_to_i_controls, bit in bits:\n        for lsb_ctrl_i in range(up_to_i_controls, 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate,  ctrl_subset + [target])\n\n        if bit == 1:\n            controls = ones[0:up_to_i_controls]\n            left = 1<<target\n            right = (L % left) + 1\n\n            wanted_cos = (left/(left + right))**0.5\n            theta = math.acos(wanted_cos)*2\n\n            gate = qis.RXGate(theta=theta)\n            if len(controls) != 0:\n                gate = gate.control(num_ctrl_qubits=len(controls))\n            qc.append(gate, controls + [target])\n            \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A5F2AFBDD89E6", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "145 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nimport qiskit.circuit.library as qis\nimport numpy as np\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    ones = []\n    one_count = 0\n\n    inds = np.arange(n)\n    lefts = np.vectorize(lambda x: 1<<x)(inds)\n    wanted_coss = np.vectorize(lambda left: (left / (left + ((L%left) + 1))) ** 0.5)(lefts)\n    thetas = np.vectorize(lambda w: math.acos(w) * 2)(wanted_coss)\n\n\n    for target in range(n-1, -1, -1):\n        bit = L & (1<<target) != 0\n\n        for lsb_ctrl_i in range(len(ones), 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate, ctrl_subset + [target], copy=False)\n\n        if bit == 1:\n            theta = thetas[target]\n\n            gate = qis.RXGate(theta=theta)\n            if one_count != 0:\n                gate = gate.control(num_ctrl_qubits=one_count)\n\n            qc.append(gate, ones + [target], copy=False)\n            \n            ones.append(target)\n            one_count += 1\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A60A8FA16A1A0", "submission_order": 1, "result": "AC", "execution_time": "1702 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if (L == 1):\n\t    return qc\n    k = math.ceil(math.log2(L))\n    qc.h(range(k)) \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A63B2B76C8CCE", "submission_order": 1, "result": "AC", "execution_time": "2376 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    k = 0\n    while True:\n        qc.h(k)\n        k += 1\n        if (1<<k) >= L:\n            break\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A653A72392169", "submission_order": 1, "result": "RE", "execution_time": "959 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport qiskit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    str_int = str(bin(L)).replace('0b', '')\n    for i in range(n)[::-1]:\n    if str_int[i] == '1':\n        cx = qiskit.circuit.library.standard_gates.ZGate().control(n-i)\n        for j in range(i):\n            qc.append(cx, list(range(i, n)[::-1]) + [j],)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A6567F0EB4DF5", "submission_order": 1, "result": "RE", "execution_time": "897 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    while L * 2 <= n\n        n //= 2\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A6567F0EB4DF5", "submission_order": 2, "result": "WA", "execution_time": "1087 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    while L * 2 <= n:\n        n //= 2\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A6567F0EB4DF5", "submission_order": 3, "result": "RE", "execution_time": "1004 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    m = 0, mk = 1\n    while mk < L:\n        m += 1\n        mk *= 2\n\n    for i in range(m):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A6567F0EB4DF5", "submission_order": 4, "result": "AC", "execution_time": "2165 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    m = 0\n    mk = 1\n    while mk < L:\n        m += 1\n        mk *= 2\n\n    for i in range(m):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A6645C8455E68", "submission_order": 1, "result": "AC", "execution_time": "2319 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = n\n    for i in range(n):\n        if L <= 2**i:\n            a = i\n            break\n    for i in range(a):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A66A621698CDE", "submission_order": 1, "result": "RE", "execution_time": "781 ms", "memory": "78 MiB", "code": "'''python\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    l = L\n    for i in range(n - 1):\n        mid = 2 ** (n - 1 - i)\n        if l >= mid:\n            theta = 2 * math.acos(math.sqrt(mid / l))\n            qc.ry(theta, n - 1 - i)\n            l -= mid\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A66A621698CDE", "submission_order": 2, "result": "RE", "execution_time": "844 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    l = L\n    for i in range(n - 1):\n        mid = 2 ** (n - 1 - i)\n        if l >= mid:\n            theta = 2 * math.acos(math.sqrt(mid / l))\n            qc.ry(theta, n - 1 - i)\n            l -= mid\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A66A621698CDE", "submission_order": 3, "result": "WA", "execution_time": "1029 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qr = qc.qregs[0]\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            pass\n        else:\n            assert L == 2\n            qc.h(0)\n        return qc.decompose()\n\n\n    mid = 2 ** (n - 1)\n    if L <= mid:\n        c = solve(n - 1, L)\n        qc.x(n - 1)\n        qc.append(c.control(1).decompose(), [qr[-1]] + qr[:-1])\n        qc.x(n - 1)\n        return qc.decompose()\n    \n    theta = 2 * math.acos(math.sqrt(mid / L))\n    qc.ry(theta, n - 1)\n    for i in range(n - 1):\n        qc.x(i)\n        qc.cx(n - 1, i)\n        qc.x(i)\n\n    c = solve(n - 1, L - mid)\n    qc.append(c.control(1).decompose(), [qr[-1]] + qr[:-1])\n    return qc.decompose()\n'''"}
{"problem": "QPC001_C1", "user": "A66A621698CDE", "submission_order": 4, "result": "WA", "execution_time": "877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qr = qc.qregs[0]\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            pass\n        else:\n            assert L == 2\n            qc.h(0)\n        return qc.decompose()\n\n\n    mid = 2 ** (n - 1)\n    if L <= mid:\n        c = solve(n - 1, L)\n        qc.x(n - 1)\n        qc.append(c.control(1).decompose(), qr)\n        qc.x(n - 1)\n        return qc.decompose()\n    \n    theta = 2 * math.acos(math.sqrt(mid / L))\n    qc.ry(theta, n - 1)\n    for i in range(n - 1):\n        qc.x(i)\n        qc.cx(n - 1, i)\n        qc.x(i)\n\n    c = solve(n - 1, L - mid)\n    qc.append(c.control(1).decompose(), qr)\n    return qc.decompose()\n'''"}
{"problem": "QPC001_C1", "user": "A66A621698CDE", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qr = qc.qregs[0]\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            pass\n        else:\n            assert L == 2\n            qc.h(0)\n        return qc.decompose()\n\n\n    mid = 2 ** (n - 1)\n    if L <= mid:\n        c = solve(n - 1, L)\n        qc.x(n - 1)\n        qc.append(c.control(1).decompose(), [qr[-1]] + qr[:-1])\n        qc.x(n - 1)\n        return qc.decompose()\n    \n    theta = 2 * math.acos(math.sqrt(mid / L))\n    qc.ry(theta, n - 1)\n    qc.x(n - 1)\n    for i in range(n - 1):\n        qc.cx(n - 1, i)\n    qc.x(n - 1)\n\n    c = solve(n - 1, L - mid)\n    qc.append(c.control(1).decompose(), [qr[-1]] + qr[:-1])\n    return qc.decompose()\n\n\nimport qiskit_aer\n\ndef run(circuit):\n    sim = qiskit_aer.AerSimulator()\n    c = circuit.copy()\n    c.save_statevector()\n    return sim.run(c, shots=1).result()\n\nif __name__ == \"__main__\":\n    n = 2\n    L = 1\n    c = solve(n, L)\n    print(c)\n    r = run(c)\n    print(r)\n'''"}
{"problem": "QPC001_C1", "user": "A66A621698CDE", "submission_order": 6, "result": "WA", "execution_time": "889 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qr = qc.qregs[0]\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            pass\n        else:\n            assert L == 2\n            qc.h(0)\n        return qc.decompose()\n\n\n    mid = 2 ** (n - 1)\n    if L <= mid:\n        c = solve(n - 1, L)\n        qc.x(n - 1)\n        qc.append(c.control(1).decompose(), [qr[-1]] + qr[:-1])\n        qc.x(n - 1)\n        return qc.decompose()\n    \n    theta = 2 * math.acos(math.sqrt(mid / L))\n    qc.ry(theta, n - 1)\n    qc.x(n - 1)\n    for i in range(n - 1):\n        qc.cx(n - 1, i)\n    qc.x(n - 1)\n\n    c = solve(n - 1, L - mid)\n    qc.append(c.control(1).decompose(), [qr[-1]] + qr[:-1])\n    return qc.decompose()\n'''"}
{"problem": "QPC001_C1", "user": "A66A621698CDE", "submission_order": 7, "result": "TLE", "execution_time": "3000 ms", "memory": "108 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qr = qc.qregs[0]\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            pass\n        else:\n            assert L == 2\n            qc.h(0)\n        return qc.decompose()\n\n\n    mid = 2 ** (n - 1)\n    if L <= mid:\n        c = solve(n - 1, L)\n        qc.x(n - 1)\n        qc.append(c.control(1).decompose(), [qr[-1]] + qr[:-1])\n        qc.x(n - 1)\n        return qc.decompose()\n    \n    theta = 2 * math.acos(math.sqrt(mid / L))\n    qc.ry(theta, n - 1)\n    qc.x(n - 1)\n    for i in range(n - 1):\n        qc.ch(n - 1, i)\n    qc.x(n - 1)\n\n    c = solve(n - 1, L - mid)\n    qc.append(c.control(1).decompose(), [qr[-1]] + qr[:-1])\n    return qc.decompose()\n'''"}
{"problem": "QPC001_C1", "user": "A66A621698CDE", "submission_order": 8, "result": "RE", "execution_time": "783 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qr = qc.qregs[0]\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            pass\n        else:\n            assert L == 2\n            qc.h(0)\n        return qc\n\n\n    mid = 2 ** (n - 1)\n    if L <= mid:\n        c = solve(n - 1, L)\n        qc.x(n - 1)\n        qc.append(c.control(1), [qr[-1]] + qr[:-1])\n        qc.x(n - 1)\n        return qc\n    \n    theta = 2 * math.acos(math.sqrt(mid / L))\n    qc.ry(theta, n - 1)\n    qc.x(n - 1)\n    for i in range(n - 1):\n        qc.ch(n - 1, i)\n    qc.x(n - 1)\n\n    c = solve(n - 1, L - mid)\n    qc.append(c.control(1), [qr[-1]] + qr[:-1])\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A6E65C67C03BA", "submission_order": 1, "result": "AC", "execution_time": "2636 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 1:\n        return qc\n    \n    qc.h(range(math.ceil(math.log2(L))))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A6E827E1D6477", "submission_order": 1, "result": "RE", "execution_time": "804 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # ランダムに複素振幅を設定\n    alphas = np.random.rand(2**n) + 1j * np.random.rand(2**n)\n\n    # 複素振幅を正規化\n    norm = np.linalg.norm(alphas)\n    normalized_alphas = alphas / norm\n\n    # 正規化された複素振幅を量子回路にセット\n    qc.initialize(normalized_alphas, range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A6F08C80DB43A", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "91 MiB", "code": "'''python\n#%%\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if 2**i < L:\n            qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A72888A0C066C", "submission_order": 1, "result": "WA", "execution_time": "1562 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A72888A0C066C", "submission_order": 2, "result": "WA", "execution_time": "1666 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A77D220D22982", "submission_order": 1, "result": "RE", "execution_time": "966 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # 各状態の振幅を等しくするため、量子回路にHゲートを適用します（必要なビット数分だけ）\n    for i in range(math.ceil(math.log(L, 2))):\n        qc.h(i)\n   \n    # 末尾に余分な状態が含まれないようにする\n    # ここではビットが少ないケースが考慮されているが、一般的な解決方法が必要です。\n    if L != 2 ** n:\n        # 未使用のビット位置を計算する\n        unused_bits = n - math.ceil(math.log(L, 2))\n        # 制御リセットゲートを未使用のビット位置に適用して、余分な状態をリセットする\n        for l in range(L, 2 ** n):\n            binary_state = bin(l)[2:].zfill(n)\n            controls = [ii for ii, bb in enumerate(reversed(binary_state)) if bb == '1']\n            if controls:\n                qc.x(controls)\n            qc.mct(controls, list(range(math.ceil(math.log(L, 2)), n)), None, mode='noancilla')\n            if controls:\n                qc.x(controls)\n    \n    return qc\n\n# トレースを除去してコードを実行するためのテスト\nif __name__ == \"__main__\":\n    n = 3\n    L = 3\n    qc = solve(n, L)\n    print(qc)\n'''"}
{"problem": "QPC001_C1", "user": "A77D220D22982", "submission_order": 2, "result": "AC", "execution_time": "1656 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # 各状態の振幅を等しくするため、量子回路にHゲートを適用します（必要なビット数分だけ）\n    for i in range(math.ceil(math.log(L, 2))):\n        qc.h(i)\n   \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A7D7437CA8BD0", "submission_order": 1, "result": "AC", "execution_time": "2053 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    if L == 1:\n        return qc\n \n    k = math.ceil(math.log2(L))\n    qc.h(range(k))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A7FAE44274EF1", "submission_order": 1, "result": "UGE", "execution_time": "787 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    amplitudes = [2 / (2 ** n) for _ in range(2 ** n - 1)]\n    amplitudes.append(1 - sum(amplitudes))\n\n    # 振幅を使用して状態を作成\n    qc.initialize(amplitudes, list(range(n)))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A80985514564C", "submission_order": 1, "result": "RE", "execution_time": "1399 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 1:\n        return qc\n    k = math.ceil(math.log2(L))\n    qc.h(range(L))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A80985514564C", "submission_order": 2, "result": "AC", "execution_time": "1914 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 1:\n        return qc\n    k = math.ceil(math.log2(L))\n    qc.h(range(k))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A8ABA8888F884", "submission_order": 1, "result": "RE", "execution_time": "787 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    k = math.ceil(math.log2(L))\n    qc.h(range(k))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A8ABA8888F884", "submission_order": 2, "result": "RE", "execution_time": "965 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    k = math.ceil(math.log2(L))\n    qc.h(range(k))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A8ABA8888F884", "submission_order": 3, "result": "AC", "execution_time": "2078 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 1:\n        return qc\n    \n    k = math.ceil(math.log2(L))\n    qc.h(range(k))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A8CC9A2757458", "submission_order": 1, "result": "AC", "execution_time": "1582 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    p=1\n    qc.h(0)\n    while((1<<p)<L):\n        qc.h(p)\n        p+=1\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A9325C94F105F", "submission_order": 1, "result": "RE", "execution_time": "971 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(len(bin(L))-2):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A9325C94F105F", "submission_order": 2, "result": "AC", "execution_time": "2765 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        for i in range(n):\n            qc.h(i)\n    else:\n        for i in range(len(bin(L))-2):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A947D54F2E79D", "submission_order": 1, "result": "RE", "execution_time": "979 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ceil,log2\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ceilL = ceil(log2(L))\n   qc.h(range(ceilL))\n\n\n   return qc\n'''"}
{"problem": "QPC001_C1", "user": "A947D54F2E79D", "submission_order": 2, "result": "AC", "execution_time": "2000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ceil,log2\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n   qc = QuantumCircuit(n)\n   ceilL = ceil(log2(L))\n   if ceilL != 0:\n      qc.h(range(ceilL))\n\n\n   return qc\n'''"}
{"problem": "QPC001_C1", "user": "A955EB597174E", "submission_order": 1, "result": "RE", "execution_time": "2119 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(L-1))\n\n    qc.ry(th, 0)\n    for i in range(L-1):\n        qc.append(RYGate(th).control(1), i, i + 1)\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A955EB597174E", "submission_order": 2, "result": "RE", "execution_time": "1895 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(L-1))\n\n    qc.ry(th, 0)\n    for i in range(L-1):\n        th = 2 * math.atan(math.sqrt(L - i - 2))\n        qc.cry(th, i, i + 1)\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A955EB597174E", "submission_order": 3, "result": "RE", "execution_time": "1742 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(L-1))\n    L =  L - 1\n    \n    qc.ry(th, 0)\n    for i in range(L-1):\n        th = 2 * math.atan(math.sqrt(L - i - 2))\n        qc.cry(th, i, i + 1)\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A955EB597174E", "submission_order": 4, "result": "RE", "execution_time": "1710 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(L-1))\n    \n    qc.ry(th, 0)\n    for i in range(L-1):\n        th = 2 * math.atan(math.sqrt(L - i - 2))\n        qc.cry(th, i, i + 1)\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A955EB597174E", "submission_order": 5, "result": "AC", "execution_time": "2395 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n        \n    qc.h(range(math.ceil(math.log2(L))))\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A97CF304D2887", "submission_order": 1, "result": "WA", "execution_time": "1017 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    target_L = 0\n    x_lst = []\n    for digit in range(n):\n        target_R = target_L + (1 << (n - digit - 1))\n        if L > target_R:\n            theta = math.asin(math.sqrt((L - target_R) / (L - target_L))) * 2\n            if(digit == 0):\n                qc.ry(theta, n-1)\n            else:\n                for i in x_lst: qc.x(i)\n                qc.append(RYGate(theta).control(digit), range(n - digit - 1, n)[::-1])\n                for i in x_lst: qc.x(i)\n            \n            target_L += (1 << (n - digit - 1))\n        else:\n            x_lst.append(n - digit - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A97CF304D2887", "submission_order": 2, "result": "AC", "execution_time": "2602 ms", "memory": "99 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == (1 << n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n\n    target_L = 0\n    x_lst = []\n    for digit in range(n):\n        target_R = target_L + (1 << (n - digit - 1))\n        if L > target_R:\n            theta = math.asin(math.sqrt((L - target_R) / (L - target_L))) * 2\n            if(digit == 0):\n                qc.ry(theta, n-1)\n            else:\n                for i in x_lst: qc.x(i)\n                qc.append(RYGate(theta).control(digit), range(n - digit - 1, n)[::-1])\n                for i in x_lst: qc.x(i)\n            \n            for i in x_lst: qc.x(i)\n            qc.x(n - digit - 1)\n            for i in range(n - digit - 1):\n                qc.append(HGate().control(digit + 1), list(range(n - digit - 1, n)) + [i])\n            for i in x_lst: qc.x(i)\n            qc.x(n - digit - 1)\n                \n            target_L += (1 << (n - digit - 1))\n        else:\n            x_lst.append(n - digit - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A99B88D483935", "submission_order": 1, "result": "WA", "execution_time": "1029 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    half = n // 2\n    i = 0\n    while half > 0:\n        if L > half:\n            break\n        qc.h(i)\n        i += 1\n        half //= 2\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A99B88D483935", "submission_order": 2, "result": "WA", "execution_time": "1062 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    half = 2**n // 2\n    i = 0\n    while half > 0:\n        if L > half:\n            break\n        qc.h(i)\n        i += 1\n        half //= 2\n    \n    return qc\n\nprint(solve(3, 3))\n'''"}
{"problem": "QPC001_C1", "user": "A99B88D483935", "submission_order": 3, "result": "WA", "execution_time": "1034 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    m = 2**n\n    i = 0\n    while m > 0:\n        if L * 2 > m:\n            break\n        qc.h(i)\n        i += 1\n        m //= 2\n    \n    return qc\n\nprint(solve(3, 3))\n'''"}
{"problem": "QPC001_C1", "user": "A99B88D483935", "submission_order": 4, "result": "WA", "execution_time": "1007 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    m = 1\n    i = n - 1\n    while m < L:\n        qc.h(i)\n        m *= 2\n        i -= 1\n\n    return qc\n\nn = 3\nfor l in range(1, 2**n + 1):\n    print(solve(n, l))\n'''"}
{"problem": "QPC001_C1", "user": "A99B88D483935", "submission_order": 5, "result": "AC", "execution_time": "2199 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    m = 1\n    i = 0\n    while m < L:\n        qc.h(i)\n        m *= 2\n        i += 1\n\n    return qc\n\nn = 3\nfor l in range(1, 2**n + 1):\n    print(solve(n, l))\n'''"}
{"problem": "QPC001_C1", "user": "A9AAD72E23849", "submission_order": 1, "result": "AC", "execution_time": "1610 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    k = math.ceil(math.log2(L))\n    for i in range(k):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A9C8EC2C5D45C", "submission_order": 1, "result": "RE", "execution_time": "3000 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    left_coeff = math.sqrt(0.6/L)\n    right_coeff = math.sqrt(0.4/(2**n-L))\n\n    coeffs = [left_coeff]*L + [right_coeff]*(2**n-L)\n    qc.initialize(coeffs, list(range(n)))\n \n    return qc.decompose(reps=5)\n'''"}
{"problem": "QPC001_C1", "user": "A9C8EC2C5D45C", "submission_order": 2, "result": "RE", "execution_time": "2584 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    left_coeff = math.sqrt(0.6/L)\n    right_coeff = math.sqrt(0.4/(2**n-L))\n\n    coeffs = [left_coeff]*L + [right_coeff]*(2**n-L)\n    qc.initialize(coeffs, list(range(n)))\n \n    return qc.decompose(reps=10)\n'''"}
{"problem": "QPC001_C1", "user": "A9C8EC2C5D45C", "submission_order": 3, "result": "AC", "execution_time": "1582 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    th = 0\n    while True:\n        if 2**th >= L:\n            break\n        else:\n            th += 1\n    \n    qc.h(range(th))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A9FCB137582F8", "submission_order": 1, "result": "RE", "execution_time": "1970 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    k = math.ceil(math.log2(L))\n    for i in range(k):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A9FCB137582F8", "submission_order": 2, "result": "RE", "execution_time": "1764 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        return qc\n    # Write your code here:\n    k = math.ceil(math.log2(L))\n    for i in range(k):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "A9FCB137582F8", "submission_order": 3, "result": "AC", "execution_time": "2603 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L == 1:\n        return qc\n\n    k = math.ceil(math.log2(L))\n    for i in range(k):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA5059C15EED5", "submission_order": 1, "result": "RE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    theta = 2*arcsin(1/sqrt(n))\n\n    qc.ry(theta, 0)\n\n    for i in range(1, n):\n        qc.ch(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA5059C15EED5", "submission_order": 2, "result": "WA", "execution_time": "1259 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import arcsin, sqrt, pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    theta = 2*arcsin(1/sqrt(n))\n\n    qc.ry(theta, 0)\n\n    for i in range(1, n):\n        qc.ch(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA5059C15EED5", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import arcsin, sqrt, p\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    theta = 2*arcsin(1/sqrt(L))\n\n    qc.ry(theta, 0)\n\n    for i in range(1, n):\n        qc.ch(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA5059C15EED5", "submission_order": 4, "result": "WA", "execution_time": "1339 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    theta = 2*np.arcsin(1/np.sqrt(L))\n\n    qc.ry(theta, 0)\n\n    for i in range(1, n):\n        qc.ch(0, i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA59A668DC89E", "submission_order": 1, "result": "RE", "execution_time": "875 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    # Tゲートを適用して位相を導入\n    for _ in range(L):\n        for qubit in range(n):\n            qc.append(TGate(), [qubit])\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA59A668DC89E", "submission_order": 2, "result": "WA", "execution_time": "1290 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, TGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    # Tゲートを適用して位相を導入\n    for _ in range(L):\n        for qubit in range(n):\n            qc.append(TGate(), [qubit])\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA59A668DC89E", "submission_order": 3, "result": "WA", "execution_time": "1241 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, TGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    # Tゲートを適用して位相を導入\n    for _ in range(L):\n        for qubit in range(n):\n            qc.append(TGate(), [qubit])\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA5D2D01F19A6", "submission_order": 1, "result": "AC", "execution_time": "1490 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 1:\n        return qc\n    \n    k = math.ceil(math.log2(L))\n    qc.h(range(k))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA7F3571AF678", "submission_order": 1, "result": "RE", "execution_time": "872 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for qubit in range(n):\n        qc.h(qubit)\n\n    # 振幅を調整\n    # 例: 最初の 'L' 状態の振幅を減少させる\n    for i in range(L):\n        angle = pi / L  # 回転角度は 'L' に応じて調整\n        qc.ry(-angle, i)  # 'ry' はY軸回転ゲート\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA7F3571AF678", "submission_order": 2, "result": "RE", "execution_time": "1053 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # すべての量子ビットにアダマールゲートを適用\n    for qubit in range(n):\n        qc.h(qubit)\n\n    # 振幅を調整\n    # 例: 最初の 'L' 状態の振幅を減少させる\n    for i in range(L):\n        angle = pi / L  # 回転角度は 'L' に応じて調整\n        qc.ry(-angle, i)  # 'ry' はY軸回転ゲート\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA85DE624ED2C", "submission_order": 1, "result": "RE", "execution_time": "1875 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    for i in range(L-1):\n        # print(i)\n        theta = 2 * math.atan(math.sqrt(n - i - 1))\n        # print(math.cos(theta/2))\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA85DE624ED2C", "submission_order": 2, "result": "AC", "execution_time": "2234 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    if L == 1:\n        return qc\n \n    k = math.ceil(math.log2(L))\n    qc.h(range(k))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA8B9F97DDDDF", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, execute\n\ndef create_equal_superposition(n: int) -> QuantumCircuit:\n    # n量子ビットの量子回路を作成\n    qc = QuantumCircuit(n)\n    \n    # 全ての量子ビットにハダマードゲートを適用\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA8B9F97DDDDF", "submission_order": 2, "result": "RE", "execution_time": "1326 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_equal_superposition(n: int) -> QuantumCircuit:\n    # n量子ビットの量子回路を作成\n    qc = QuantumCircuit(n)\n    \n    # 全ての量子ビットにハダマードゲートを適用\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA8B9F97DDDDF", "submission_order": 3, "result": "RE", "execution_time": "1319 ms", "memory": "141 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef create_equal_superposition(n: int) -> QuantumCircuit:\n    # n量子ビットの量子レジスタを作成\n    qreg = QuantumRegister(n)\n    qc = QuantumCircuit(qreg)\n    \n    # 各量子ビットにハダマードゲートを適用してスーパー・ポジションを作成\n    for i in range(n):\n        qc.append(HGate(), [qreg[i]])\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AA8B9F97DDDDF", "submission_order": 4, "result": "RE", "execution_time": "1330 ms", "memory": "141 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate, MCPhaseGate\n\ndef create_custom_superposition(n: int) -> QuantumCircuit:\n    # n量子ビットの量子レジスタと回路を作成\n    qr = QuantumRegister(n, 'q')\n    qc = QuantumCircuit(qr)\n    \n    # 全ての量子ビットにハダマードゲートを適用\n    for i in range(n):\n        qc.append(HGate(), [qr[i]])\n    \n    # 位相を調整して、実数部が0.5以上になるようにする\n    phase_angle = math.acos(0.5)  # cos(phase_angle) = 0.5\n    for i in range(1, n):\n        qc.append(MCPhaseGate(phase_angle, num_ctrl_qubits=i), list(range(i + 1)))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AAB1BC4124CC1", "submission_order": 1, "result": "AC", "execution_time": "2144 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n + 1):\n    if L <= (1 << i):\n      for j in range(i):\n        qc.h(j)\n      return qc\n'''"}
{"problem": "QPC001_C1", "user": "AAE72742F214B", "submission_order": 1, "result": "WA", "execution_time": "1114 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n\n    prob_amp = math.sqrt(1 / 3)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 0, 1)\n    qc.cx(1, 0)\n\n    prob_amp = math.sqrt(1 / 2)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 1, 0)\n\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n\"\"\"\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(5)\n\n    for i in range(1, n + 1):\n        if L <= 2 ** i:\n            iter = i - 1\n            front = 2 ** iter\n            back = L - front\n            break\n    \n\n    for i in range(1, iter + 1):\n        front_prob_amp = math.sqrt(front / L)\n        front_rot_ang = 2 * math.acos(front_prob_amp)\n        back_prob_amp = math.sqrt(back / L)\n        back_rot_ang = 2 * math.acos(back_prob_amp)\n\n    prob_amp = math.sqrt(1 / 7)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 0, 1)\n    qc.cx(1, 0)\n\n    prob_amp = math.sqrt(1 / 6)\n    rot_ang = 2 * math.acos(prob_amp)\n    qc.cry(rot_ang, 1, 0)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n\n\nprob_amp = math.sqrt(1 / 3)\nrot_ang = 2 * math.acos(prob_amp)\nprint(rot_ang)\n'''"}
{"problem": "QPC001_C1", "user": "AAE72742F214B", "submission_order": 2, "result": "AC", "execution_time": "1712 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 1:\n        return qc\n    \n    k = math.ceil(math.log2(L))\n    qc.h(range(k))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB014621B4C68", "submission_order": 1, "result": "AC", "execution_time": "2966 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if 2 ** i >= L:\n            break\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB101C91093E6", "submission_order": 1, "result": "AC", "execution_time": "1877 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L==2**n:\n        qc.h(range(int(math.log2(L))))\n    else:\n        qc.h(range(1+int(math.log2(L))))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB2243C8A0D29", "submission_order": 1, "result": "WA", "execution_time": "2028 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    M = L\n    i = n-1\n    if (L>>i)&1 == 0:\n        qc.x(i)\n    else:\n        theta = -2*math.acos(math.sqrt(2**i/M))\n        qc.x(i)\n        qc.ry(theta,i)\n        CH = HGate().control(n-i)\n        for j in range(i):\n            qc.append(CH,list(range(n-1,i-1,-1))+[j])\n        qc.x(i)\n        M -= 2**i\n    for i in range(n-2,-1,-1):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n        else:\n            theta = -2*math.acos(math.sqrt(2**i/M))\n            qc.x(i)\n            qc.append(RYGate(theta).control(n-i-1),range(n-1,i-1,-1))\n            CH = HGate().control(n-i)\n            for j in range(i):\n                qc.append(CH,list(range(n-1,i-1,-1))+[j])\n            qc.x(i)\n            M -= 2**i\n        qc_copy = qc.copy()\n        for j in range(n-1,i-1,-1):\n            if (L>>j)&1 == 0:\n                qc_copy.x(j)\n    for i in range(n-1,-1,-1):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB2243C8A0D29", "submission_order": 2, "result": "RE", "execution_time": "2138 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==(1<<n):\n        for i in range(n):\n            qc.h(i)\n    else:\n        M = L\n        i = n-1\n        if (L>>i)&1 == 0:\n            qc.x(i)\n        else:\n            theta = -2*math.acos(math.sqrt(2**i/M))\n            qc.x(i)\n            qc.ry(theta,i)\n            CH = HGate().control(n-i)\n            for j in range(i):\n                qc.append(CH,list(range(n-1,i-1,-1))+[j])\n            qc.x(i)\n            M -= 2**i\n        for i in range(n-2,-1,-1):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n            else:\n                theta = -2*math.acos(math.sqrt(2**i/M))\n                qc.x(i)\n                qc.append(RYGate(theta).control(n-i-1),range(n-1,i-1,-1))\n                CH = HGate().control(n-i)\n                for j in range(i):\n                    qc.append(CH,list(range(n-1,i-1,-1))+[j])\n                qc.x(i)\n                M -= 2**i\n            qc_copy = qc.copy()\n            for j in range(n-1,i-1,-1):\n                if (L>>j)&1 == 0:\n                    qc_copy.x(j)\n        for i in range(n-1,-1,-1):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n        return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB2243C8A0D29", "submission_order": 3, "result": "AC", "execution_time": "1998 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==(1<<n):\n        for i in range(n):\n            qc.h(i)\n    else:\n        M = L\n        i = n-1\n        if (L>>i)&1 == 0:\n            qc.x(i)\n        else:\n            theta = -2*math.acos(math.sqrt(2**i/M))\n            qc.x(i)\n            qc.ry(theta,i)\n            CH = HGate().control(n-i)\n            for j in range(i):\n                qc.append(CH,list(range(n-1,i-1,-1))+[j])\n            qc.x(i)\n            M -= 2**i\n        for i in range(n-2,-1,-1):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n            else:\n                theta = -2*math.acos(math.sqrt(2**i/M))\n                qc.x(i)\n                qc.append(RYGate(theta).control(n-i-1),range(n-1,i-1,-1))\n                CH = HGate().control(n-i)\n                for j in range(i):\n                    qc.append(CH,list(range(n-1,i-1,-1))+[j])\n                qc.x(i)\n                M -= 2**i\n        for i in range(n-1,-1,-1):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB4D0A7F29248", "submission_order": 1, "result": "RE", "execution_time": "932 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = math.ceil(math.log2(L))\n    for i in range(l):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB4D0A7F29248", "submission_order": 2, "result": "RE", "execution_time": "1035 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = math.ceil(math.log2(L))\n    for i in range(l):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB4D0A7F29248", "submission_order": 3, "result": "AC", "execution_time": "2117 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = math.ceil(math.log2(L))\n    for i in range(l):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB7B0E7897EC8", "submission_order": 1, "result": "WA", "execution_time": "853 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB7B0E7897EC8", "submission_order": 2, "result": "RE", "execution_time": "1121 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L > 2**{n-1}\n        for i in range(n):\n            qc.h(i)\n    else:\n        qc.x(n-1)\n        qc.h(n-1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB7B0E7897EC8", "submission_order": 3, "result": "WA", "execution_time": "1013 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    if L < 2**(n-1):\n        qc.x(n-1)\n        qc.h(n-1)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB7B0E7897EC8", "submission_order": 4, "result": "AC", "execution_time": "1684 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for k in range(1, n):\n        print(k)\n        if L <= 2**(n-k):\n            qc.x(n-k)\n            qc.h(n-k)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB8EC0D67E097", "submission_order": 1, "result": "WA", "execution_time": "1094 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB8EC0D67E097", "submission_order": 2, "result": "RE", "execution_time": "866 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.cp(-2 * np.pi / (2**n), n-1, 0)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AB915911306AE", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    while True:\n        print(n)\n        if L > 2 ** (n - 1):\n            qc.h(range(n))\n            return qc\n        n -= 1\n'''"}
{"problem": "QPC001_C1", "user": "ABA496B11F030", "submission_order": 1, "result": "RE", "execution_time": "875 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qubit_num = 1\n    while 2**qubit_num < L:\n    qubit_num += 1\n\n    qc = QuantumCircuit(n)\n\n    qc.h(range(n-qubit_num,n))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ABA496B11F030", "submission_order": 2, "result": "WA", "execution_time": "1336 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qubit_num = 1\n    while 2**qubit_num < L:\n        qubit_num += 1\n\n    qc.h(range(n-qubit_num,n))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ABA496B11F030", "submission_order": 3, "result": "AC", "execution_time": "1765 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qubit_num = 1\n    while 2**qubit_num < L:\n        qubit_num += 1\n\n    qc.h(range(qubit_num))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ABC282C81693F", "submission_order": 1, "result": "RE", "execution_time": "1147 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m = None\n    for i in list(range(n))[::-1]:\n        if L & (2 ** i):\n            m = i\n    for i in range(m):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ABC282C81693F", "submission_order": 2, "result": "RE", "execution_time": "837 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    M = L\n    # Write your code here:\n    ls = [i for i in range(n) if get_bit(M, i)]\n    for l in ls:\n        qc.x(l)\n    l0 = ls[0]\n    l1 = ls[1]\n    M0 = 2 ** l0\n    if l0 > 0:\n        for i in range(l0):\n            qc.h(i)\n    theta0 = -2 * acos(sqrt(M0 / M))\n    qc.ry(theta0, l1)\n    qc.x(l1)\n    for i in range(l0, l1):\n        qc.ch(l1, i)\n    qc.x(l1)\n\n    k = len(ls) - 1\n\n    Mm = M0\n\n    for m in range(1, k):\n        theta_m = -2 * acos(sqrt(2 ** ls[m] / (M - Mm)))\n        qc.x(l[m])\n        qc.cry(theta_m, l[m+1], l[m])\n        qc.x(l[m])\n        qc.x(l[m+1])\n        for i in range(l[m], l[m+1]):\n            qc.ch(l[m+1], i)\n        qc.x(l[m+1])\n        Mm = Mm + 2 ** l[m]\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ABC282C81693F", "submission_order": 3, "result": "RE", "execution_time": "879 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    M = L\n    # Write your code here:\n    ls = [i for i in range(n) if get_bit(M, i)]\n    if len(ls) == 0:\n        return qc\n    for l in ls:\n        qc.x(l)\n    l0 = ls[0]\n    if len(ls) == 1:\n        for i in range(l0):\n            qc.h(i)\n        return qc\n    l1 = ls[1]\n    M0 = 2 ** l0\n    if l0 > 0:\n        for i in range(l0):\n            qc.h(i)\n    theta0 = -2 * acos(sqrt(M0 / M))\n    qc.ry(theta0, l1)\n    qc.x(l1)\n    for i in range(l0, l1):\n        qc.ch(l1, i)\n    qc.x(l1)\n\n    k = len(ls) - 1\n\n    Mm = M0\n\n    for m in range(1, k):\n        theta_m = -2 * acos(sqrt(2 ** ls[m] / (M - Mm)))\n        qc.x(l[m])\n        qc.cry(theta_m, l[m+1], l[m])\n        qc.x(l[m])\n        qc.x(l[m+1])\n        for i in range(l[m], l[m+1]):\n            qc.ch(l[m+1], i)\n        qc.x(l[m+1])\n        Mm = Mm + 2 ** l[m]\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ABC282C81693F", "submission_order": 4, "result": "WA", "execution_time": "1022 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    M = L\n    # Write your code here:\n    ls = [i for i in range(n) if get_bit(M, i)]\n    if len(ls) == 0:\n        return qc\n    for l in ls:\n        qc.x(l)\n    l0 = ls[0]\n    if len(ls) == 1:\n        for i in range(l0):\n            qc.h(i)\n        return qc\n    l1 = ls[1]\n    M0 = 2 ** l0\n    if l0 > 0:\n        for i in range(l0):\n            qc.h(i)\n    theta0 = -2 * acos(sqrt(M0 / M))\n    qc.ry(theta0, l1)\n    qc.x(l1)\n    for i in range(l0, l1):\n        qc.ch(l1, i)\n    qc.x(l1)\n\n    k = len(ls) - 1\n\n    Mm = M0\n\n    for m in range(1, k):\n        theta_m = -2 * acos(sqrt(2 ** ls[m] / (M - Mm)))\n        qc.x(ls[m])\n        qc.cry(theta_m, ls[m], ls[m+1])\n        qc.x(ls[m])\n        qc.x(ls[m+1])\n        for i in range(ls[m], ls[m+1]):\n            qc.ch(ls[m+1], i)\n        qc.x(ls[m+1])\n        Mm = Mm + 2 ** ls[m]\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ABC282C81693F", "submission_order": 5, "result": "WA", "execution_time": "1212 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    M = L\n    # Write your code here:\n    ls = [i for i in range(n) if get_bit(M, i)]\n    if len(ls) == 0:\n        return qc\n    for l in ls[1:]:\n        qc.x(l)\n\n    l0 = ls[0]\n    if len(ls) == 1:\n        for i in range(l0):\n            qc.h(i)\n        return qc\n    \n    l1 = ls[1]\n    M0 = 2 ** l0\n    if l0 > 0:\n        for i in range(l0):\n            qc.h(i)\n    theta0 = -2 * acos(sqrt(M0 / M))\n    qc.ry(theta0, l1)\n\n    qc.x(l1)\n    for i in range(l0, l1):\n        qc.ch(l1, i)\n    qc.x(l1)\n\n    k = len(ls) - 1\n\n    Mm = M0\n\n    for m in range(1, k):\n        theta_m = -2 * acos(sqrt(2 ** ls[m] / (M - Mm)))\n        qc.x(ls[m])\n        qc.cry(theta_m, ls[m], ls[m+1])\n        qc.x(ls[m])\n        qc.x(ls[m+1])\n        for i in range(ls[m], ls[m+1]):\n            qc.ch(ls[m+1], i)\n        qc.x(ls[m+1])\n        Mm = Mm + 2 ** ls[m]\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ABC282C81693F", "submission_order": 6, "result": "AC", "execution_time": "2309 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    M = L\n    # Write your code here:\n    ls = [i for i in range(n) if get_bit(M, i)]\n    if len(ls) == 0:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    for l in ls[1:]:\n        qc.x(l)\n\n    l0 = ls[0]\n    if len(ls) == 1:\n        print(l0)\n        for i in range(l0):\n            qc.h(i)\n        return qc\n    \n    l1 = ls[1]\n    M0 = 2 ** l0\n    if l0 > 0:\n        for i in range(l0):\n            qc.h(i)\n    theta0 = -2 * acos(sqrt(M0 / M))\n    qc.ry(theta0, l1)\n\n    qc.x(l1)\n    for i in range(l0, l1):\n        qc.ch(l1, i)\n    qc.x(l1)\n\n    k = len(ls) - 1\n\n    Mm = M0\n\n    for m in range(1, k):\n        theta_m = -2 * acos(sqrt(2 ** ls[m] / (M - Mm)))\n        qc.x(ls[m])\n        qc.cry(theta_m, ls[m], ls[m+1])\n        qc.x(ls[m])\n        qc.x(ls[m+1])\n        for i in range(ls[m], ls[m+1]):\n            qc.ch(ls[m+1], i)\n        qc.x(ls[m+1])\n        Mm = Mm + 2 ** ls[m]\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC35B6F2F802E", "submission_order": 1, "result": "AC", "execution_time": "2155 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(math.ceil(math.log2(L))):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC3782F05998E", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import ZGate,XGate,RYGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n\n    # Write your code here:\n    \n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 - start), range(start,qubits))\n        else:\n            qc.z(start)\n\n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    from collections import defaultdict\n    d=defaultdict(int)\n    for i in range(L):\n        s=bin(i)[2:].rjust(n,\"0\")\n        tmp=\"\"\n        for i in s:\n            tmp+=i\n            d[tmp]+=1\n\n    # 指定したbit(ゼロ状態)が0になる確率をratioにする\n\n    # 指定したcontroll bitがすべて1の場合にbit(ゼロ状態)が0になる確率をratioにする    \n    def crotate(qc,bits,p0):\n        theta=math.acos(p0*2-1)\n        if len(bits)==1:\n            qc.ry(theta,bits[0])\n        else:\n            qc.append(RYGate(theta).control(len(bits)-1),bits)\n\n    import time\n\n    \n    def dfs(prefix,bit,qc,n):\n        # print(\"call\",prefix,bit)\n        prefix0=prefix+\"0\"\n        prefix1=prefix+\"1\"\n        v=int(prefix.ljust(n,\"0\"),2)\n\n\n        if d[prefix0]+d[prefix1]==0:return\n        if prefix==\"\":\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            to_calcable(n,qc,v,0)\n            crotate(qc,[bit],p0)\n            to_calcable(n,qc,v,0)\n            dfs(prefix0,bit-1,qc,n)\n            dfs(prefix1,bit-1,qc,n)\n        elif bit>=0:\n            # print(prefix,d[prefix+\"0\"],d[prefix+\"1\"])\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            if p0==0.5:\n                to_calcable(n,qc,v,0)\n                for b in range(bit,-1,-1):\n                    crotate(qc,list(range(n-1,bit,-1))+[b],p0)\n                to_calcable(n,qc,v,0)\n            else:\n                to_calcable(n,qc,v,0)\n                crotate(qc,list(range(n-1,bit-1,-1)),p0)\n                to_calcable(n,qc,v,0)\n                dfs(prefix0,bit-1,qc,n)\n                dfs(prefix1,bit-1,qc,n)\n\n    dfs(\"\",n-1,qc,n)\n    # depth = qc.depth()\n    # print(\"量子回路の深さ:\", depth)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC3782F05998E", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import ZGate,XGate,RYGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(nn)\n    \n\n    # Write your code here:\n    \n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 - start), range(start,qubits))\n        else:\n            qc.z(start)\n\n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    from collections import defaultdict\n    d=defaultdict(int)\n    for i in range(L):\n        s=bin(i)[2:].rjust(n,\"0\")\n        tmp=\"\"\n        for i in s:\n            tmp+=i\n            d[tmp]+=1\n\n    # 指定したbit(ゼロ状態)が0になる確率をratioにする\n\n    # 指定したcontroll bitがすべて1の場合にbit(ゼロ状態)が0になる確率をratioにする    \n    def crotate(qc,bits,p0):\n        theta=math.acos(p0*2-1)\n        if len(bits)==1:\n            qc.ry(theta,bits[0])\n        else:\n            qc.append(RYGate(theta).control(len(bits)-1),bits)\n\n    \n    def dfs(prefix,bit,qc,n):\n        # print(\"call\",prefix,bit)\n        prefix0=prefix+\"0\"\n        prefix1=prefix+\"1\"\n        v=int(prefix.ljust(n,\"0\"),2)\n\n\n        if d[prefix0]+d[prefix1]==0:return\n        if prefix==\"\":\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            to_calcable(n,qc,v,0)\n            crotate(qc,[bit],p0)\n            to_calcable(n,qc,v,0)\n            dfs(prefix0,bit-1,qc,n)\n            dfs(prefix1,bit-1,qc,n)\n        elif bit>=0:\n            # print(prefix,d[prefix+\"0\"],d[prefix+\"1\"])\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            if p0==0.5:\n                to_calcable(n,qc,v,0)\n                for b in range(bit,-1,-1):\n                    crotate(qc,list(range(n-1,bit,-1))+[b],p0)\n                to_calcable(n,qc,v,0)\n            else:\n                to_calcable(n,qc,v,0)\n                crotate(qc,list(range(n-1,bit-1,-1)),p0)\n                to_calcable(n,qc,v,0)\n                dfs(prefix0,bit-1,qc,n)\n                dfs(prefix1,bit-1,qc,n)\n\n    dfs(\"\",n-1,qc,n)\n    # depth = qc.depth()\n    # print(\"量子回路の深さ:\", depth)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC3782F05998E", "submission_order": 3, "result": "AC", "execution_time": "1911 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import ZGate,XGate,RYGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n\n    # Write your code here:\n    \n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 - start), range(start,qubits))\n        else:\n            qc.z(start)\n\n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    d={}\n    for i in range(1<<n):\n        tmp=\"\"\n        for j in bin(i)[2:].rjust(n,\"0\"):\n            tmp+=j\n            d.setdefault(tmp,0)\n\n    for i in range(L):\n        s=bin(i)[2:].rjust(n,\"0\")\n        tmp=\"\"\n        for i in s:\n            tmp+=i\n            d[tmp]+=1\n\n    # 指定したbit(ゼロ状態)が0になる確率をratioにする\n\n    # 指定したcontroll bitがすべて1の場合にbit(ゼロ状態)が0になる確率をratioにする    \n    def crotate(qc,bits,p0):\n        theta=math.acos(p0*2-1)\n        if len(bits)==1:\n            qc.ry(theta,bits[0])\n        else:\n            qc.append(RYGate(theta).control(len(bits)-1),bits)\n\n    \n    def dfs(prefix,bit,qc,n):\n        # print(\"call\",prefix,bit)\n        prefix0=prefix+\"0\"\n        prefix1=prefix+\"1\"\n        v=int(prefix.ljust(n,\"0\"),2)\n\n\n        if bit==-1 or d.get(prefix0)+d.get(prefix1)==0:return\n        if prefix==\"\":\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            to_calcable(n,qc,v,0)\n            crotate(qc,[bit],p0)\n            to_calcable(n,qc,v,0)\n            dfs(prefix0,bit-1,qc,n)\n            dfs(prefix1,bit-1,qc,n)\n        elif bit>=0:\n            # print(prefix,d[prefix+\"0\"],d[prefix+\"1\"])\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            if p0==0.5:\n                to_calcable(n,qc,v,0)\n                for b in range(bit,-1,-1):\n                    crotate(qc,list(range(n-1,bit,-1))+[b],p0)\n                to_calcable(n,qc,v,0)\n            else:\n                to_calcable(n,qc,v,0)\n                crotate(qc,list(range(n-1,bit-1,-1)),p0)\n                to_calcable(n,qc,v,0)\n                dfs(prefix0,bit-1,qc,n)\n                dfs(prefix1,bit-1,qc,n)\n\n    dfs(\"\",n-1,qc,n)\n    # depth = qc.depth()\n    # print(\"量子回路の深さ:\", depth)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC429BDA9461C", "submission_order": 1, "result": "WA", "execution_time": "1797 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC429BDA9461C", "submission_order": 2, "result": "WA", "execution_time": "2075 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC429BDA9461C", "submission_order": 3, "result": "AC", "execution_time": "1931 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    c=0\n    while 2**c<L:\n        c+=1\n\n    for i in range(c):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC5D25D2C039C", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (1 << i) < L:\n            qc.h(i)\n    return qc\n\nif False && __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    import numpy as np\n\n    qc = solve(3, 3)\n    sv = Statevector(qc)\n    print(sv)\n    prob = np.abs(sv) ** 2\n    print(sum(prob[i] for i in range(3)))\n    # sv = Statevector.from_label('+++')\n    # print(sv.evolve(qc))\n'''"}
{"problem": "QPC001_C1", "user": "AC5D25D2C039C", "submission_order": 2, "result": "AC", "execution_time": "2411 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (1 << i) < L:\n            qc.h(i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(3, 3)\n#     sv = Statevector(qc)\n#     print(sv)\n#     prob = np.abs(sv) ** 2\n#     print(sum(prob[i] for i in range(3)))\n#     # sv = Statevector.from_label('+++')\n#     # print(sv.evolve(qc))\n'''"}
{"problem": "QPC001_C1", "user": "AC68857A2AA48", "submission_order": 1, "result": "AC", "execution_time": "1329 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    k=1\n    while 2**k<L:\n        k+=1\n    \n    for i in range(k):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC81613DA472D", "submission_order": 1, "result": "RE", "execution_time": "1010 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.mcx([0, 1, 2], 3)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC81613DA472D", "submission_order": 2, "result": "WA", "execution_time": "998 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(0, int(math.log(L))+1):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC81613DA472D", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit import Aer, execute\n\nfrom qiskit.circuit.library import RYGate, HGate\nfrom math import acos, sqrt, log2\nimport math\n\n\ndef f(n, L):\n    # 量子レジスタと量子回路の作成\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n\n    if L == 1:\n        qc.h(qr[0])\n        return qc\n\n    # Lで1が立っている最上位ビットをkとする\n    k = int(log2(L))\n\n    # kビット目にRYゲートを適用\n    theta = acos(sqrt((L - 2**int(log2(L)))/L)) * 2\n    qc.append(RYGate(theta), [qr[k]])\n\n    # kビットを制御ビットとして残りのビットにHadamardゲートを適用\n    ch_gate = HGate().control()\n    for i in range(k):\n        qc.x(qr[k])\n        qc.append(ch_gate, [qr[k], qr[i]])\n        qc.x(qr[k])\n\n    # kビットが1の場合、再帰的に関数を呼び出す\n    if L > 2 ** k:\n        sub_qc = f(n, L - 2**k)\n        qc.compose(sub_qc, qr, inplace=True)\n\n    return qc\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    return f(n, L)\n'''"}
{"problem": "QPC001_C1", "user": "AC81613DA472D", "submission_order": 4, "result": "RE", "execution_time": "1066 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate, HGate\nfrom math import acos, sqrt, log2\nimport math\n\n\ndef f(n, L):\n    # 量子レジスタと量子回路の作成\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n\n    if L == 1:\n        qc.h(qr[0])\n        return qc\n\n    # Lで1が立っている最上位ビットをkとする\n    k = int(log2(L))\n\n    # kビット目にRYゲートを適用\n    theta = acos(sqrt((L - 2**int(log2(L)))/L)) * 2\n    qc.append(RYGate(theta), [qr[k]])\n\n    # kビットを制御ビットとして残りのビットにHadamardゲートを適用\n    ch_gate = HGate().control()\n    for i in range(k):\n        qc.x(qr[k])\n        qc.append(ch_gate, [qr[k], qr[i]])\n        qc.x(qr[k])\n\n    # kビットが1の場合、再帰的に関数を呼び出す\n    if L > 2 ** k:\n        sub_qc = f(n, L - 2**k)\n        qc.compose(sub_qc, qr, inplace=True)\n\n    return qc\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    return f(n, L)\n'''"}
{"problem": "QPC001_C1", "user": "AC81613DA472D", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit import Aer, execute\n\nfrom qiskit.circuit.library import RYGate, HGate\nfrom math import acos, sqrt, log2\nimport math\n\n\ndef f(n, L):\n    # 量子レジスタと量子回路の作成\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n\n    if L == 1:\n        return qc\n\n    # Lで1が立っている最上位ビットをkとする\n    k = int(log2(L))\n\n    # kビット目にRYゲートを適用\n    theta = acos(sqrt(2**int(log2(L))/L)) * 2\n    qc.append(RYGate(theta), [qr[k]])\n\n    ch_gate = HGate().control()\n    for i in range(k):\n        qc.x(qr[k])\n        qc.append(ch_gate, [qr[k], qr[i]])\n        qc.x(qr[k])\n\n    if L > 2 ** k:\n        sub_qc = f(k, L - 2**k)\n        sub_inst = sub_qc.control()\n        qc.append(sub_inst, [qr[k]] + qr[:k])\n\n\n\n    print(qc)\n    return qc\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    return f(n, L)\n'''"}
{"problem": "QPC001_C1", "user": "AC81613DA472D", "submission_order": 6, "result": "RE", "execution_time": "1054 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import RYGate, HGate\nfrom math import acos, sqrt, log2\nimport math\n\n\ndef f(n, L):\n    # 量子レジスタと量子回路の作成\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n\n    if L == 1:\n        return qc\n\n    # Lで1が立っている最上位ビットをkとする\n    k = int(log2(L))\n\n    # kビット目にRYゲートを適用\n    theta = acos(sqrt(2**int(log2(L))/L)) * 2\n    qc.append(RYGate(theta), [qr[k]])\n\n    ch_gate = HGate().control()\n    for i in range(k):\n        qc.x(qr[k])\n        qc.append(ch_gate, [qr[k], qr[i]])\n        qc.x(qr[k])\n\n    if L > 2 ** k:\n        sub_qc = f(k, L - 2**k)\n        sub_inst = sub_qc.control()\n        qc.append(sub_inst, [qr[k]] + qr[:k])\n\n\n\n    print(qc)\n    return qc\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    return f(n, L)\n'''"}
{"problem": "QPC001_C1", "user": "AC81613DA472D", "submission_order": 7, "result": "RE", "execution_time": "818 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import RYGate, HGate, XGate\nfrom math import acos, sqrt, log2\nimport math\n\n\ndef f(n, L):\n    # 量子レジスタと量子回路の作成\n    # qr = QuantumRegister(n)\n    # qc = QuantumCircuit(qr)\n    gates = []\n\n    if L == 1:\n        # return qc\n        return gates\n\n    # Lで1が立っている最上位ビットをkとする\n    k = int(log2(L))\n\n    # kビット目にRYゲートを適用\n    theta = acos(sqrt(2**int(log2(L))/L)) * 2\n    gates.append((RYGate(theta), [k]))\n    # qc.append(RYGate(theta), [qr[k]])\n\n    ch_gate = HGate().control()\n    for i in range(k):\n        # qc.x(qr[k])\n        # qc.append(ch_gate, [qr[k], qr[i]])\n        # qc.x(qr[k])\n        gates.append([XGate(), [k]])\n        gates.append([ch_gate, [k, i]])\n        gates.append([XGate(), [k]])\n\n\n    if L - 1 > 2 ** k:\n        sub_gates = f(k, L - 2**k)\n        # sub_inst = sub_qc.control()\n        # qc.append(sub_inst, [qr[k]] + qr[:k])\n        # gates.append([(gate[0].control() for gate in sub_gates, [k] + [i for i in range(k)])])\n        gates.extend([(gate[0].control(), [k] + gate[1]) for gate in sub_gates])\n\n    return gates\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    gates = f(n, L)\n    qc = QuantumCircuit(n)\n    print(\"\\n\")\n    print(gates)\n    for gate in gates:\n        print(\"\\n\")\n        print(gate)\n        qc.append(gate[0], gate[1])\n\n    #swap endian\n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC81613DA472D", "submission_order": 8, "result": "RE", "execution_time": "1404 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import RYGate, HGate, XGate\nfrom math import acos, sqrt, log2\nimport math\n\n\ndef f(n, L):\n    # 量子レジスタと量子回路の作成\n    # qr = QuantumRegister(n)\n    # qc = QuantumCircuit(qr)\n    gates = []\n\n    if L == 1:\n        # return qc\n        return gates\n\n    # Lで1が立っている最上位ビットをkとする\n    k = int(log2(L))\n\n    # kビット目にRYゲートを適用\n    theta = acos(sqrt(2**int(log2(L))/L)) * 2\n    gates.append((RYGate(theta), [k]))\n    # qc.append(RYGate(theta), [qr[k]])\n\n    ch_gate = HGate().control()\n    for i in range(k):\n        gates.append([XGate(), [k]])\n        gates.append([ch_gate, [k, i]])\n        gates.append([XGate(), [k]])\n\n\n    if L - 1 > 2 ** k:\n        sub_gates = f(k, L - 2**k)\n        # sub_inst = sub_qc.control()\n        # qc.append(sub_inst, [qr[k]] + qr[:k])\n        # gates.append([(gate[0].control() for gate in sub_gates, [k] + [i for i in range(k)])])\n        gates.extend([(gate[0].control(), [k] + gate[1]) for gate in sub_gates])\n\n    return gates\n\n\ndef solve(n: int, L) -> QuantumCircuit:\n    gates = f(n, L)\n    qc = QuantumCircuit(n)\n    for gate in gates:\n        qc.append(gate[0], gate[1])\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AC9C953AF12E2", "submission_order": 1, "result": "WA", "execution_time": "901 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AD2708D2EDE24", "submission_order": 1, "result": "AC", "execution_time": "1989 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (1 << i) < L:\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AD49168EE898D", "submission_order": 1, "result": "AC", "execution_time": "1895 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      if (1 << i) < L:\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AD65F9EFF5FD1", "submission_order": 1, "result": "WA", "execution_time": "1802 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if 2**n > L:\n            break\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AD65F9EFF5FD1", "submission_order": 2, "result": "AC", "execution_time": "2070 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if 2**i > L:\n            break\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADA72424235CF", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i = 0\n    while 2**i < L:\n        qc.h(i)\n        i += 1\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 1, "result": "RE", "execution_time": "2003 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    # 必要な量子ビットの数を計算\n    num_qubits = max(n, math.ceil(math.log2(L+1)))\n    qc = QuantumCircuit(num_qubits)\n\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            # 1量子ビットの場合、通常のZゲートを使用\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n    \n    qc.rz(math.pi, range(num_qubits))\n    qc.x(num_qubits-1)\n    # すべての量子ビットが0の場合にのみ作用する制御Zゲートを作成\n    controls = list(range(num_qubits-1))\n    target = num_qubits-1\n    qc.append(ZGate().control(len(controls)), controls + [target])\n\n    # 最後の量子ビットに再度Xゲートを適用\n    qc.x(num_qubits-1)\n\n    # すべての量子ビットにアダマールゲートを適用\n    qc.h(range(num_qubits))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 2, "result": "RE", "execution_time": "965 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef grover_search(n, L):\n    num_qubits = max(n, math.ceil(math.log2(L+1)))\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n\n    # オラクルと拡散演算子の適用\n    for _ in range(int(math.sqrt(2**num_qubits))):\n        oracle(qc, num_qubits, L)\n        diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 3, "result": "WA", "execution_time": "910 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = max(n, math.ceil(math.log2(L+1)))\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n\n    # オラクルと拡散演算子の適用\n    for _ in range(int(math.sqrt(2**num_qubits))):\n        oracle(qc, num_qubits, L)\n        diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 4, "result": "RE", "execution_time": "2170 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n\n    # オラクルと拡散演算子の適用\n    for _ in range(10):\n        oracle(qc, num_qubits, L)\n        diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 5, "result": "RE", "execution_time": "1083 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n\n    # オラクルと拡散演算子の適用\n    for _ in range(10):\n        oracle(qc, num_qubits, L)\n        diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 6, "result": "RE", "execution_time": "1042 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n\n    # オラクルと拡散演算子の適用\n    for _ in range(int(math.sqrt(num_qubits))):\n        oracle(qc, num_qubits, L)\n        diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 7, "result": "WA", "execution_time": "940 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        #qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        #qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n\n    # オラクルと拡散演算子の適用\n    for _ in range(int(math.sqrt(num_qubits))):\n        oracle(qc, num_qubits, L)\n        diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 8, "result": "WA", "execution_time": "1059 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        #qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        #qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n    if L!=n**2:\n        # オラクルと拡散演算子の適用\n        for _ in range(int(math.sqrt(num_qubits))):\n            oracle(qc, num_qubits, L)\n            diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 9, "result": "WA", "execution_time": "1403 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        #qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        qc.x([qubit for qubit, bit in enumerate(state) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        #qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        qc.x([qubit for qubit, bit in enumerate(state) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n    if L!=2**n:\n        # オラクルと拡散演算子の適用\n        for _ in range(int(math.sqrt(num_qubits))):\n            oracle(qc, num_qubits, L)\n            diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 10, "result": "WA", "execution_time": "1305 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        #qc.x([qubit for qubit, bit in enumerate(state) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state[::-1]) if bit == '0'])\n        #qc.x([qubit for qubit, bit in enumerate(state) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n    if L!=2**n:\n        # オラクルと拡散演算子の適用\n        for _ in range(num_qubits):\n            oracle(qc, num_qubits, L)\n            diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 11, "result": "WA", "execution_time": "1249 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(L):\n        state = format(i, '0' + str(num_qubits) + 'b')[::-1]\n        qc.x([qubit for qubit, bit in enumerate(state) if bit == '0'])\n        \n        if num_qubits > 1:\n            qc.append(ZGate().control(num_qubits-1), qc.qubits)\n        else:\n            qc.z(0)\n\n        qc.x([qubit for qubit, bit in enumerate(state) if bit == '0'])\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n    if L!=2**n:\n        # オラクルと拡散演算子の適用\n        for _ in range(num_qubits):\n            oracle(qc, num_qubits, L)\n            diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "ADE96F597E7BF", "submission_order": 12, "result": "RE", "execution_time": "916 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate, XGate\nimport math\n\ndef oracle(qc, num_qubits, L):\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(ZGate().control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n\ndef diffusion_operator(qc, num_qubits):\n    qc.h(range(num_qubits))\n    qc.x(range(num_qubits))\n    \n    if num_qubits > 1:\n        qc.append(ZGate().control(num_qubits-1), range(num_qubits))\n    else:\n        qc.z(0)\n    \n    qc.x(range(num_qubits))\n    qc.h(range(num_qubits))\n\ndef solve(n, L):\n    num_qubits = n\n    qc = QuantumCircuit(num_qubits)\n\n    # 初期化\n    qc.h(range(num_qubits))\n    if L!=2**n:\n        # オラクルと拡散演算子の適用\n        for _ in range(num_qubits):\n            oracle(qc, num_qubits, L)\n            diffusion_operator(qc, num_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 1, "result": "WA", "execution_time": "976 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    same = ''\n    for i in range(n-1, -1, -1):\n        nxt = L >> i & 1\n        if nxt == 1:\n            if i == n-1:\n                qc.x(i)\n                qc.z(i)\n                qc.x(i)\n            else:\n                qc.x(i)\n                qc.append(ZGate().control(n-i-1, ctrl_state=same), range(n-1, i-1, -1))\n                qc.x(i)\n        same = str(nxt) + same\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 2, "result": "WA", "execution_time": "1257 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    same = ''\n    for i in range(n-1, -1, -1):\n        nxt = L >> i & 1\n        if nxt == 0:\n            if i == n-1:\n                qc.h(i)\n            else:\n                qc.x(i)\n                qc.append(HGate().control(n-i-1, ctrl_state=same), range(n-1, i-1, -1))\n                qc.x(i)\n        same = str(nxt) + same\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 3, "result": "WA", "execution_time": "1383 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    same = ''\n    for i in range(n-1, -1, -1):\n        nxt = L >> i & 1\n        if nxt == 0:\n            if i == n-1:\n                qc.h(i)\n            else:\n                qc.append(HGate().control(n-i-1, ctrl_state=same), range(n-1, i-1, -1))\n        same = str(nxt) + same\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 4, "result": "RE", "execution_time": "1028 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        lower_mask = (1 << (i+1)) - 1\n        cnt = [0] * (1 << (i+1))\n        for j in range(L):\n            cnt[j & lower_mask] += 1\n        for j in range(1 << i):\n            cnt_0 = cnt[j << 1]\n            cnt_1 = cnt[(j << 1) + 1]\n            theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n            if i == 0:\n                qc.append(RYGate(theta), [i])\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=(bin(j)[2:].zfill(i))[::-1]), list(range(i+1)))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 5, "result": "TLE", "execution_time": "3000 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        lower_mask = (1 << (i+1)) - 1\n        cnt = [0] * (1 << (i+1))\n        for j in range(L):\n            cnt[j & lower_mask] += 1\n        for j in range(1 << i):\n            cnt_0 = cnt[j << 1]\n            cnt_1 = cnt[(j << 1) + 1]\n            if cnt_0 + cnt_1 == 0:\n                continue\n            theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n            if i == 0:\n                qc.append(RYGate(theta), [i])\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=(bin(j)[2:].zfill(i))[::-1]), list(range(i+1)))\n \n    return qc\n\nprint(solve(10, 911))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 6, "result": "WA", "execution_time": "1014 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        lower_mask = (1 << (i+1)) - 1\n        l_low = L & lower_mask\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = l_low >> j & 1\n            if nxt == 1:\n                if j == i-1:\n                    qc.h(j)\n                else:\n                    qc.append(HGate().control(i-j-1, ctrl_state=same), range(i-1, j-1, -1))\n            same = str(nxt) + same\n        cnt_0 = L >> i\n        cnt_1 = cnt_0 + 1\n        theta = math.asin(-math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = l_low >> j & 1\n            if nxt == 0:\n                if j == i-1:\n                    qc.x(j)\n                    qc.h(j)\n                    qc.x(j)\n                else:\n                    qc.append(RYGate(theta).control(i-j-1, ctrl_state=same), range(i-1, j-1, -1))\n            same = str(nxt) + same\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 7, "result": "WA", "execution_time": "1267 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & ((1 << i) - 1) == 0:\n            qc.h(i)\n            continue\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 1:\n                qc.append(HGate().control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        cnt_0 = L >> i\n        cnt_1 = cnt_0 + 1\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 0:\n                qc.append(RYGate(theta).control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        qc.append(RYGate(theta).control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n \n    return qc\n\nprint(solve(3, 6))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 8, "result": "WA", "execution_time": "1179 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 1:\n                qc.append(HGate().control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        cnt_0 = L >> i\n        cnt_1 = cnt_0 + 1\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 0:\n                qc.append(RYGate(theta).control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        if i == 0:\n            qc.ry(theta, 0)\n        else:\n            qc.append(RYGate(theta).control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 9, "result": "RE", "execution_time": "870 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 1:\n                qc.append(HGate().control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        cnt_0 = L >> (i+1) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 0:\n                qc.append(RYGate(theta).control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        if i == 0:\n            qc.ry(theta, 0)\n        else:\n            qc.append(RYGate(theta).control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 10, "result": "RE", "execution_time": "923 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 1:\n                qc.append(HGate().control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        cnt_0 = L >> (i+1) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 0:\n                qc.append(RYGate(theta).control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        if i == 0:\n            qc.ry(theta, 0)\n        else:\n            qc.append(RYGate(theta).control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 11, "result": "WA", "execution_time": "1246 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 1:\n                qc.append(HGate().control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 0:\n                qc.append(RYGate(theta).control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        if i == 0:\n            qc.ry(theta, 0)\n        else:\n            qc.append(RYGate(theta).control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 12, "result": "WA", "execution_time": "1452 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + (L >> i & 1 ^ 1)\n        cnt_1 = L >> (i+1)\n        if cnt_0 + cnt_1 != 0:\n            theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n                same = str(nxt) + same\n        cnt_0 = (L >> (i+1)) + (L >> i & 1)\n        cnt_1 = L >> (i+1)\n        if cnt_0 + cnt_1 != 0:\n            theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n                same = str(nxt) + same\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 13, "result": "WA", "execution_time": "1324 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L >> i & 1 == 1:\n            cnt_0 = (L >> (i+1)) + 1\n            cnt_1 = L >> (i+1) + 1\n            theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n            qc.ry(theta, i)\n            continue\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 1:\n                qc.append(RYGate(theta).control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        same = ''\n        for j in range(i-1, -1, -1):\n            nxt = L >> j & 1\n            if nxt == 0:\n                qc.append(HGate().control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n            same = str(nxt) + same\n        if i == 0:\n            qc.h(0)\n        else:\n            qc.append(HGate().control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 14, "result": "TLE", "execution_time": "3000 ms", "memory": "105 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n                same = str(nxt) + same\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n                same = str(nxt) + same\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state='0'+same), list(range(i-1, j-1, -1)) + [i])\n                same = str(nxt) + same\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state='1'+same), list(range(i-1, j-1, -1)) + [i])\n                same = str(nxt) + same\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), list(range(i-1, -1, -1)) + [i])\n \n    return qc\n\nprint(solve(3, 5))\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 15, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                same += str(nxt)\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                same += str(nxt)\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                same += str(nxt)\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                same += str(nxt)\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 16, "result": "TLE", "execution_time": "3000 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    strings = ['']\n    for i in range(n):\n        strings.append(strings[-1] + str(L >> i & 1))\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n\nsolve(10, 999)\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 17, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    strings = ['']\n    for i in range(n):\n        strings.append(strings[-1] + str(L >> i & 1))\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 18, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    strings = ['']\n    for i in range(n):\n        strings.append(strings[-1] + str(L >> i & 1))\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same << 1), range(j, i+1))\n                    same = same << 1 | 1\n                else:\n                    same = same << 1\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same << 1 | 1), range(j, i+1))\n                    same = same << 1\n                else:\n                    same = same << 1 | 1\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same << 1), range(j, i+1))\n                    same = same << 1 | 1\n                else:\n                    same = same << 1\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same << 1 | 1), range(j, i+1))\n                    same = same << 1\n                else:\n                    same = same << 1 | 1\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 19, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same << 1), range(j, i+1))\n                    same = same << 1 | 1\n                else:\n                    same = same << 1\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same << 1 | 1), range(j, i+1))\n                    same = same << 1\n                else:\n                    same = same << 1 | 1\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same << 1), range(j, i+1))\n                    same = same << 1 | 1\n                else:\n                    same = same << 1\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same << 1 | 1), range(j, i+1))\n                    same = same << 1\n                else:\n                    same = same << 1 | 1\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 20, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same << 1), list(range(j, i+1)))\n                    same = same << 1 | 1\n                else:\n                    same = same << 1\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same << 1 | 1), list(range(j, i+1)))\n                    same = same << 1\n                else:\n                    same = same << 1 | 1\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), list(range(i+1)))\n        else:\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same << 1), list(range(j, i+1)))\n                    same = same << 1 | 1\n                else:\n                    same = same << 1\n            same = 0\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same << 1 | 1), list(range(j, i+1)))\n                    same = same << 1\n                else:\n                    same = same << 1 | 1\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), list(range(i+1)))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 21, "result": "TLE", "execution_time": "3000 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    strings = ['']\n    for i in range(n):\n        strings.append(strings[-1] + str(L >> i & 1))\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n\nsolve(10, 999)\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 22, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                same += str(nxt)\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                same += str(nxt)\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                same += str(nxt)\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                same += str(nxt)\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 23, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    strings = ['']\n    for i in range(n):\n        strings.append(strings[-1] + str(L >> i & 1))\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 24, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    strings = ['']\n    for i in range(n):\n        strings.append(strings[-1] + str(L >> i & 1))\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 25, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    if L == (1 << n):\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n        return qc\n    if L == 1:\n        qc = QuantumCircuit(n)\n        return qc\n    qc = QuantumCircuit(n)\n    strings = ['']\n    for i in range(n):\n        strings.append(strings[-1] + str(L >> i & 1))\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 26, "result": "TLE", "execution_time": "3000 ms", "memory": "99 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    for i in range(0, n+1):\n        if L == (1 << i):\n            qc = QuantumCircuit(n)\n            for j in range(i):\n                qc.h(j)\n            return qc\n    if L == 1:\n        qc = QuantumCircuit(n)\n        return qc\n    qc = QuantumCircuit(n)\n    strings = ['']\n    for i in range(n):\n        strings.append(strings[-1] + str(L >> i & 1))\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 27, "result": "TLE", "execution_time": "3000 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    for i in range(0, n+1):\n        if L == (1 << i):\n            qc = QuantumCircuit(n)\n            for j in range(i):\n                qc.h(j)\n            return qc\n    if L == 1:\n        qc = QuantumCircuit(n)\n        return qc\n    qc = QuantumCircuit(n)\n    l = [0] * n\n    for i in range(n):\n        l[i] = L >> i & 1\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if l[i] == 1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                if l[j] == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                if l[j] == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                if l[j] == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = l[j]\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 28, "result": "WA", "execution_time": "1103 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    for i in range(0, n+1):\n        if L == (1 << i):\n            qc = QuantumCircuit(n)\n            for j in range(i):\n                qc.h(j)\n            return qc\n    if L == 1:\n        qc = QuantumCircuit(n)\n        return qc\n    qc = QuantumCircuit(n)\n    l = [0] * n\n    for i in range(n):\n        l[i] = L >> i & 1\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2 - math.pi\n        if l[i] == 1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                if l[j] == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                if l[j] == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE15290718CDA", "submission_order": 29, "result": "AC", "execution_time": "2687 ms", "memory": "98 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    for i in range(0, n+1):\n        if L == (1 << i):\n            qc = QuantumCircuit(n)\n            for j in range(i):\n                qc.h(j)\n            return qc\n    if L == 1:\n        qc = QuantumCircuit(n)\n        return qc\n    qc = QuantumCircuit(n)\n    l = [0] * n\n    for i in range(n):\n        l[i] = L >> i & 1\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2 - math.pi / 2\n        if l[i] == 1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                if l[j] == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                    same += '0'\n                else:\n                    same += '1'\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                if l[j] == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                    same += '1'\n                else:\n                    same += '0'\n \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE2745B977F7E", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n    else:\n        k = math.ceil(math.log2(L))\n        qc.h(range(k))\n        \n        return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE2A712B6934B", "submission_order": 1, "result": "WA", "execution_time": "1245 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE2A712B6934B", "submission_order": 2, "result": "WA", "execution_time": "1050 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(math.ceil(math.log2(n))):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE2A712B6934B", "submission_order": 3, "result": "AC", "execution_time": "2455 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(math.ceil(math.log2(L))):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE2FDBACE828A", "submission_order": 1, "result": "AC", "execution_time": "1746 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    k=math.ceil(math.log2(L))\n    for i in range(k):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE55480461410", "submission_order": 1, "result": "AC", "execution_time": "2960 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = 1\n    m = 0\n    while l < L:  \n        l *= 2\n        m += 1\n    for i in range(m):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AE817E3B1CEA2", "submission_order": 1, "result": "AC", "execution_time": "1509 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(max(1, math.ceil(math.log2(L)))))\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AEA960CEBCB89", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\nimport numpy as np\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.h(i)\n\n    if L != 2**n:\n        angle = 2 * np.pi / (2**n)\n        for i in range(L, 2**n):\n            qc.p(-angle * i, range(n))\n        qc.append(QFT(n, inverse=True), range(n))\n\n        for i in range(L, 2**n):\n            qc.p(angle * i, range(n))\n\n        qc.append(QFT(n), range(n))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AEA960CEBCB89", "submission_order": 2, "result": "RE", "execution_time": "1129 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_qubits_for_superposition = math.ceil(math.log2(L))\n    for i in range(num_qubits_for_superposition):\n        qc.h(i)\n\n    if 2**num_qubits_for_superposition > L:\n        for i in range(L, 2**num_qubits_for_superposition):\n            binary_form = format(i, '0' + str(num_qubits_for_superposition) + 'b')[::-1]\n            controls = [j for j, bit in enumerate(binary_form) if bit == '1']\n\n            if controls:\n                qc.mcp(math.pi, controls, num_qubits_for_superposition)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AEA960CEBCB89", "submission_order": 3, "result": "RE", "execution_time": "930 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_qubits_for_superposition = math.ceil(math.log2(L))\n    for i in range(num_qubits_for_superposition):\n        qc.h(i)\n\n    if 2**num_qubits_for_superposition > L:\n        additional_qubit = num_qubits_for_superposition\n        qc.h(additional_qubit)\n\n        for i in range(L, 2**num_qubits_for_superposition):\n            binary_form = format(i, '0' + str(num_qubits_for_superposition) + 'b')[::-1]\n            controls = [j for j, bit in enumerate(binary_form) if bit == '1']\n\n            if controls:\n                qc.mcrx(math.pi, controls, additional_qubit)\n\n        qc.h(additional_qubit)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AEA960CEBCB89", "submission_order": 4, "result": "AC", "execution_time": "1519 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if L == 1:\n        return qc\n \n    k = math.ceil(math.log2(L))\n#    print(\"k:\",str(k))\n    qc.h(range(k))\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AEC8B64C73646", "submission_order": 1, "result": "RE", "execution_time": "788 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    sz = L\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        prob = (1<<pos)/sz\n        print(pos, prob, sz, 1<<pos)\n        theta = math.acos(math.sqrt(prob))\n        if i == 0:\n            qc.ry(2.0 * theta,pos)\n        else:\n            qc.cry(2.0 * theta,bit_position[i-1],pos)\n        sz -= (1<<pos)\n\n    bit_position.reverse()\n    for i in range(len(bit_position)-1):\n        pos = bit_position[i]\n        if pos == 0:\n            continue\n        print(pos, (1<<pos))\n        custom = HGate().control(2,ctrl_state=\"10\")\n        for j in range(pos):\n            print(j,pos,bit_position[i+1])\n            qc.append(custom,[pos,bit_position[i+1],j])\n\n    qc.ch(bit_position[-1],range(bit_position[-1]),ctrl_state=0)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AEC8B64C73646", "submission_order": 2, "result": "RE", "execution_time": "846 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L==1:\n        return qc\n    if n==1:\n        qc.h(0)\n        return qc\n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    # print(bit_position)\n    sz = L\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        prob = (1<<pos)/sz\n        # print(pos, prob, sz, 1<<pos)\n        theta = math.acos(math.sqrt(prob))\n        if i == 0:\n            qc.ry(2.0 * theta,pos)\n        else:\n            qc.cry(2.0 * theta,bit_position[i-1],pos)\n        sz -= (1<<pos)\n\n    bit_position.reverse()\n    for i in range(len(bit_position)-1):\n        pos = bit_position[i]\n        if pos == 0:\n            continue\n        custom = HGate().control(2,ctrl_state=\"10\")\n        for j in range(pos):\n            qc.append(custom,[pos,bit_position[i+1],j])\n    if bit_position[-1] != 0:\n        qc.ch(bit_position[-1],range(bit_position[-1]),ctrl_state=0)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AEC8B64C73646", "submission_order": 3, "result": "AC", "execution_time": "2650 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L==1:\n        return qc\n    if n==1:\n        qc.h(0)\n        return qc\n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    # print(bit_position)\n    sz = L\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        prob = (1<<pos)/sz\n        # print(pos, prob, sz, 1<<pos)\n        theta = math.acos(math.sqrt(prob))\n        if i == 0:\n            qc.ry(2.0 * theta,pos)\n        else:\n            qc.cry(2.0 * theta,bit_position[i-1],pos)\n        sz -= (1<<pos)\n\n    bit_position.reverse()\n    for i in range(len(bit_position)-1):\n        pos = bit_position[i]\n        if pos == 0:\n            continue\n        custom = HGate().control(2,ctrl_state=\"10\")\n        for j in range(pos):\n            qc.append(custom,[pos,bit_position[i+1],j])\n    if bit_position[-1] != 0:\n        qc.ch(bit_position[-1],range(bit_position[-1]),ctrl_state=0)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AECF1798910A7", "submission_order": 1, "result": "AC", "execution_time": "2026 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 1:\n        pass\n    else:\n        cnt = math.ceil(math.log2(L))\n        for i in range(cnt):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AF13D8159C8D6", "submission_order": 1, "result": "AC", "execution_time": "2046 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L >> i: qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AF2293BC16B02", "submission_order": 1, "result": "AC", "execution_time": "1822 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# from qiskit.quantum_info import Statevector\n\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m = (L-1).bit_length()\n    for i in range(m):\n        qc.h(i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3, 3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC001_C1", "user": "AF5881B8AF985", "submission_order": 1, "result": "AC", "execution_time": "2332 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = 0\n    while (2**l<L):\n        l += 1\n    for i in range(l):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AF5DB207FAF45", "submission_order": 1, "result": "WA", "execution_time": "925 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AFE27F2C0DFF4", "submission_order": 1, "result": "RE", "execution_time": "821 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    lis = []\n    k = L\n    tmp = 0\n    while(k>0):\n        if k%2:\n            lis = lis + [tmp]\n        tmp += 1\n        k = k //2\n    m = 2 ** (lis[0])\n    if len(lis) == 1:\n        for i in range(lis[0]):\n            qc.h(i)\n        return qc\n    \n    for i in range(1,len(lis)):\n        qc.x(lis[i])\n    if lis[0] > 0:\n        for i in range(lis[0]):\n            qc.h(i)\n    qc.ry(-2*math.acos(math.sqrt(m / L)), lis[1])\n    qc.x(lis[1])\n    for i in range(lis[0],lis[1]):\n        qc.ch(lis[1], i)\n    qc.x(lis[1])        \n    for i in range(1,len(lis) - 1):\n        qc.x(lis[i]) \n        qc.cry(-2 * math.acos(math.sqrt(2 ** lis[i] / (L - m))), lis[i], lis[i+1])\n        qc.x(lis[i])\n        qc.x(lis[i+1])\n        for j in range(lis[i],lis[i+1]):\n            qc.ch(lis[i+1],j)\n        qc.x(lis[i+1])\n        m = m + 2 ** (lis[i])\n    return qc\n'''"}
{"problem": "QPC001_C1", "user": "AFE27F2C0DFF4", "submission_order": 2, "result": "AC", "execution_time": "1419 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    lis = []\n    k = L\n    tmp = 0\n    while(k>0):\n        if k%2:\n            lis = lis + [tmp]\n        tmp += 1\n        k = k //2\n    m = 2 ** (lis[0])\n    if len(lis) == 1:\n        for i in range(lis[0]):\n            qc.h(i)\n        return qc\n    \n    for i in range(1,len(lis)):\n        qc.x(lis[i])\n    if lis[0] > 0:\n        for i in range(lis[0]):\n            qc.h(i)\n    qc.ry(-2*math.acos(math.sqrt(m / L)), lis[1])\n    qc.x(lis[1])\n    for i in range(lis[0],lis[1]):\n        qc.ch(lis[1], i)\n    qc.x(lis[1])        \n    for i in range(1,len(lis) - 1):\n        qc.x(lis[i]) \n        qc.cry(-2 * math.acos(math.sqrt(2 ** lis[i] / (L - m))), lis[i], lis[i+1])\n        qc.x(lis[i])\n        qc.x(lis[i+1])\n        for j in range(lis[i],lis[i+1]):\n            qc.ch(lis[i+1],j)\n        qc.x(lis[i+1])\n        m = m + 2 ** (lis[i])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A032BE31C3665", "submission_order": 1, "result": "RE", "execution_time": "1750 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(n):\n        qc = less_than(qc,n,L)\n        for i in range(n):\n            qc.h(i)\n        \n        qc = less_than(qc,n,2**n)\n        \n        for i in range(n):\n            qc.x(i)\n        \n        qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            qc.x(i)\n\n    \n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n\n\n\ndef less_than(qc,n,L):\n    l = L\n\n    lst = []\n    \n    if l == 2**n:\n        l = l//2;\n\n    while (l > 0):\n        if l & 1 == 1:\n            lst.append(1)\n        else:\n            lst.append(0)\n        l = l >> 1\n        \n    lst.reverse()\n\n    k = [0 for i in range(n - len(lst))]\n    lst = k + lst\n\n\n    for i in range(len(lst)):\n        if lst[i] == 1:\n            qc.x(n-i-1)\n            if i > 0:\n                qc.append(ZGate().control(i), range(n-i-1,n))\n            else:\n                qc.z(n-i-1)\n            qc.x(n-i-1)\n        else:\n            qc.x(n-i-1)\n\n    for i in range(len(lst)):\n        if lst[i] == 0:\n            qc.x(n-i-1)\n            \n    if L == 2**n:\n        qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A032BE31C3665", "submission_order": 2, "result": "RE", "execution_time": "984 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(int(math.sqrt(2**n))):\n        qc = less_than(qc,n,L)\n        for i in range(n):\n            qc.h(i)\n        \n        qc = less_than(qc,n,2**n)\n        \n        for i in range(n):\n            qc.x(i)\n        \n        qc.append(ZGate().control(n-1), range(n))\n\n        for i in range(n):\n            qc.x(i)\n\n    \n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n\n\n\ndef less_than(qc,n,L):\n    l = L\n\n    lst = []\n    \n    if l == 2**n:\n        l = l//2;\n\n    while (l > 0):\n        if l & 1 == 1:\n            lst.append(1)\n        else:\n            lst.append(0)\n        l = l >> 1\n        \n    lst.reverse()\n\n    k = [0 for i in range(n - len(lst))]\n    lst = k + lst\n\n\n    for i in range(len(lst)):\n        if lst[i] == 1:\n            qc.x(n-i-1)\n            if i > 0:\n                qc.append(ZGate().control(i), range(n-i-1,n))\n            else:\n                qc.z(n-i-1)\n            qc.x(n-i-1)\n        else:\n            qc.x(n-i-1)\n\n    for i in range(len(lst)):\n        if lst[i] == 0:\n            qc.x(n-i-1)\n            \n    if L == 2**n:\n        qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A04F9DA8619A4", "submission_order": 1, "result": "WA", "execution_time": "1207 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_keta = 1\n    for i in range(n):\n        if 2**i <= L:\n            L_keta = i+1\n\n    for i in range(L_keta):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A089EB4D37E05", "submission_order": 1, "result": "TLE", "execution_time": "4000 ms", "memory": "108 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, XGate\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\n\ndef append_cry(qc, angle, ctrl_lst, tgt):\n    if ctrl_lst:\n        # 制御量子ビットがある場合、制御RYゲートを追加\n        qc.append(RYGate(angle).control(len(ctrl_lst)), ctrl_lst + [tgt])\n    else:\n        # 制御量子ビットがない場合、通常のRYゲートを追加\n        qc.ry(angle, tgt)\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    dq = [(0,n,L)]\n    while dq:\n        x,m,l = dq.pop(0)\n        #print(x,m,l)\n        if l == 0 or m == 0:\n            continue\n        left = min(2**(m-1),l)\n        right = l-left\n        # 処理\n        for j in range(m,n):\n            if not (x>>j)&1:\n                qc.x(j)\n        append_cry(qc, 2*math.acos((left/l)**0.5),[_ for _ in range(m,n)],m-1)\n        for j in range(m,n):\n            if not (x>>j)&1:\n                qc.x(j)\n        # 追加\n        #continue\n        dq.append((x,m-1,left))\n        dq.append((x+2**(m-1),m-1,right))\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A089EB4D37E05", "submission_order": 2, "result": "AC", "execution_time": "3933 ms", "memory": "98 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nimport math\nfrom qiskit import QuantumCircuit\n\n\ndef append_cry(qc, angle, ctrl_lst, tgt):\n    if ctrl_lst:\n        # 制御量子ビットがある場合、制御RYゲートを追加\n        qc.append(RYGate(angle).control(len(ctrl_lst)), ctrl_lst + [tgt])\n    else:\n        # 制御量子ビットがない場合、通常のRYゲートを追加\n        qc.ry(angle, tgt)\n\ndef append_ch(qc, ctrl_lst, tgt):\n    if ctrl_lst:\n        # 制御量子ビットがある場合、制御Hゲートを追加\n        qc.append(HGate().control(len(ctrl_lst)), ctrl_lst + [tgt])\n    else:\n        # 制御量子ビットがない場合、通常のHゲートを追加\n        qc.h(tgt)\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    dq = [(0,n,L)]\n    while dq:\n        x,m,l = dq.pop(0)\n        #print(x,m,l)\n        if l == 0 or m == 0:\n            continue\n        \n        if l == 2**m:\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            for j in range(m):\n                append_ch(qc,[_ for _ in range(m,n)],j)\n            for j in range(m,n):\n                if not (x>>j)&1:\n                    qc.x(j)\n            continue\n\n\n        left = min(2**(m-1),l)\n        right = l-left\n\n\n        # 処理2\n        for j in range(m,n):\n            if not (x>>j)&1:\n                qc.x(j)\n        append_cry(qc, 2*math.acos((left/l)**0.5),[_ for _ in range(m,n)],m-1)\n        for j in range(m,n):\n            if not (x>>j)&1:\n                qc.x(j)\n        # 追加2\n        dq.append((x,m-1,left))\n        dq.append((x+2**(m-1),m-1,right))\n\n\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A0B6CB2CD251B", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport mat\n\ndef Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n\n    return qc\n\ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n    qc.x(range(n))\n    return qc\n\ndef U(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(max(1, math.ceil(math.log2(L)))))\n    return qc\n\ndef Um(n: int, L: int, m: int, u: QuantumCircuit, r_t: QuantumCircuit, r_s: QuantumCircuit) -> QuantumCircuit:\n    if m == 0:\n        return U(n, L)\n    u_m_1 = Um(n, L, m - 1, u, r_t, r_s)\n    return u_m_1.compose(r_t).compose(u_m_1.inverse()).compose(r_s).compose(u_m_1)\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    u = U(n, L)\n    r_t = Rt(n, L)\n    r_s = Rs(n)\n    um = Um(n, L, 2, u, r_t, r_s)\n    return um\n'''"}
{"problem": "QPC001_C2", "user": "A0B6CB2CD251B", "submission_order": 2, "result": "AC", "execution_time": "4424 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n\n    return qc\n\ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n    qc.x(range(n))\n    return qc\n\ndef U(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(max(1, math.ceil(math.log2(L)))))\n    return qc\n\ndef Um(n: int, L: int, m: int, u: QuantumCircuit, r_t: QuantumCircuit, r_s: QuantumCircuit) -> QuantumCircuit:\n    if m == 0:\n        return U(n, L)\n    u_m_1 = Um(n, L, m - 1, u, r_t, r_s)\n    return u_m_1.compose(r_t).compose(u_m_1.inverse()).compose(r_s).compose(u_m_1)\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    u = U(n, L)\n    r_t = Rt(n, L)\n    r_s = Rs(n)\n    um = Um(n, L, 2, u, r_t, r_s)\n    return um\n'''"}
{"problem": "QPC001_C2", "user": "A0E0EED7ADAF9", "submission_order": 1, "result": "AC", "execution_time": "2215 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==2**n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    \n    v = 0\n    for i in range(n-1, -1, -1):\n        if (L>>i)&1:\n            for j in range(n-1, i, -1):\n                if ((v>>j)&1)==0:\n                    qc.x(j)\n            if (v^(1<<i))<L:\n                if i==n-1:\n                    qc.ry(math.acos(math.sqrt(2**i/(L-v)))*2, i)\n                else:\n                    qc.append(RYGate(theta=math.acos(math.sqrt(2**i/(L-v)))*2).control(n-i-1), list(range(i+1, n))+[i])\n            qc.x(i)\n            for j in range(i):\n                qc.append(HGate().control(n-i), list(range(i, n))+[j])\n            for j in range(n-1, i-1, -1):\n                if ((v>>j)&1)==0:\n                    qc.x(j)\n            v ^= (1<<i)\n    # print(qc.depth())\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(10, 1023)\n    # print(Statevector(qc))\n'''"}
{"problem": "QPC001_C2", "user": "A0EF3DEE54B06", "submission_order": 1, "result": "AC", "execution_time": "4390 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\ndef Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n\n    return qc\n\n\ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n\n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n\n    qc.x(range(n))\n\n    return qc\n\n\ndef U(m: int, n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if m == 0:\n        qc.h(range(n))\n        return qc\n\n    u = U(m - 1, n, L)\n\n    qc.compose(u, inplace=True)\n    qc.compose(Rt(n, L), inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(Rs(n), inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    k = math.ceil(math.log2(L))\n    if k == 0:\n        return qc\n\n    m = 2\n    qc.compose(U(m, k, L), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A1145E5472B0F", "submission_order": 1, "result": "AC", "execution_time": "3372 ms", "memory": "99 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == (1 << n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n\n    target_L = 0\n    x_lst = []\n    for digit in range(n):\n        target_R = target_L + (1 << (n - digit - 1))\n        if L > target_R:\n            theta = math.asin(math.sqrt((L - target_R) / (L - target_L))) * 2\n            if(digit == 0):\n                qc.ry(theta, n-1)\n            else:\n                for i in x_lst: qc.x(i)\n                qc.append(RYGate(theta).control(digit), range(n - digit - 1, n)[::-1])\n                for i in x_lst: qc.x(i)\n            \n            for i in x_lst: qc.x(i)\n            qc.x(n - digit - 1)\n            for i in range(n - digit - 1):\n                qc.append(HGate().control(digit + 1), list(range(n - digit - 1, n)) + [i])\n            for i in x_lst: qc.x(i)\n            qc.x(n - digit - 1)\n                \n            target_L += (1 << (n - digit - 1))\n        else:\n            x_lst.append(n - digit - 1)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A1322A49F0DA3", "submission_order": 1, "result": "WA", "execution_time": "1150 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A1B5FFDEDE65C", "submission_order": 1, "result": "WA", "execution_time": "1118 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n    flip_ind = []\n    left = L\n    for i in reversed(range(n)):\n        if L&(1<<i) :\n            if i == n-1:\n                qc.ry(2*math.acos(math.sqrt((1<<i)/L)),i)\n                qc.x(i)\n                for j in range(i):\n                    qc.ch(i,j)\n                qc.x(i)\n            else:\n                for y in flip_ind:\n                    qc.x(y)\n                qc.mcry(2*math.acos(math.sqrt((1<<i)/left)),list(range(i+1,n)),i)\n                qc.x(i)\n                for j in range(i):\n                    qc.mcrx(math.pi,list(range(i+1,n)),i)\n                    qc.mcrz(math.pi,list(range(i+1,n)),i)\n                    qc.mcrx(math.pi,list(range(i+1,n)),i)\n                qc.x(i)\n                for y in flip_ind:\n                    qc.x(y)\n            left -= (1<<i)\n        else:\n            flip_ind.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A1B5FFDEDE65C", "submission_order": 2, "result": "UGE", "execution_time": "853 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n    flip_ind = []\n    left = L\n    for i in reversed(range(n)):\n        if L&(1<<i) :\n            if i == n-1:\n                qc.ry(2*math.acos(math.sqrt((1<<i)/L)),i)\n                qc.x(i)\n                for j in range(i):\n                    qc.ch(i,j)\n                qc.x(i)\n            else:\n                for y in flip_ind:\n                    qc.x(y)\n                qc.mcry(2*math.acos(math.sqrt((1<<i)/left)),list(range(i+1,n)),i)\n                qc.x(i)\n                for j in range(i):\n                    qc.mcrx(math.pi/2,list(range(i,n)),j)\n                    qc.mcrz(math.pi/2,list(range(i,n)),j)\n                    qc.mcrx(math.pi/2,list(range(i,n)),j)\n                qc.x(i)\n                for y in flip_ind:\n                    qc.x(y)\n            left -= (1<<i)\n        else:\n            flip_ind.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A1B5FFDEDE65C", "submission_order": 3, "result": "UGE", "execution_time": "999 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n    flip_ind = []\n    left = L\n    for i in reversed(range(n)):\n        if L&(1<<i) :\n            if i == n-1:\n                qc.ry(2*math.acos(math.sqrt((1<<i)/L)),i)\n                qc.x(i)\n                for j in range(i):\n                    qc.ch(i,j)\n                qc.x(i)\n            else:\n                for y in flip_ind:\n                    qc.x(y)\n                MCMT.mcry(qc,theta=2*math.acos(math.sqrt((1<<i)/left)),q_controls=list(range(i+1,n)),q_target=i)\n                qc.x(i)\n                for j in range(i):\n                    MCMT.mcrx(qc,theta=math.pi/2,q_controls=list(range(i,n)),q_target=j)\n                    MCMT.mcrz(qc,lam=math.pi/2,q_controls=list(range(i,n)),q_target=j)\n                    MCMT.mcrx(qc,theta=math.pi/2,q_controls=list(range(i,n)),q_target=j)\n                    # qc += MCMT.mcrx(math.pi/2,list(range(i,n)),j)\n                    # qc += MCMT.mcrz(math.pi/2,list(range(i,n)),j)\n                    # qc += MCMT.mcrx(math.pi/2,list(range(i,n)),j)\n                qc.x(i)\n                for y in flip_ind:\n                    qc.x(y)\n            left -= (1<<i)\n        else:\n            flip_ind.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A1B5FFDEDE65C", "submission_order": 4, "result": "DLE", "execution_time": "1484 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n    flip_ind = []\n    left = L\n    for i in reversed(range(n)):\n        if L&(1<<i) :\n            if i == n-1:\n                qc.ry(2*math.acos(math.sqrt((1<<i)/L)),i)\n                qc.x(i)\n                for j in range(i):\n                    qc.ch(i,j)\n                qc.x(i)\n            else:\n                for y in flip_ind:\n                    qc.x(y)\n                MCMT.mcry(qc,theta=2*math.acos(math.sqrt((1<<i)/left)),q_controls=list(range(i+1,n)),q_target=i,use_basis_gates=True)\n                qc.x(i)\n                for j in range(i):\n                    MCMT.mcrx(qc,theta=math.pi/2,q_controls=list(range(i,n)),q_target=j,use_basis_gates=True)\n                    MCMT.mcrz(qc,lam=math.pi/2,q_controls=list(range(i,n)),q_target=j,use_basis_gates=True)\n                    MCMT.mcrx(qc,theta=math.pi/2,q_controls=list(range(i,n)),q_target=j,use_basis_gates=True)\n                    # qc += MCMT.mcrx(math.pi/2,list(range(i,n)),j)\n                    # qc += MCMT.mcrz(math.pi/2,list(range(i,n)),j)\n                    # qc += MCMT.mcrx(math.pi/2,list(range(i,n)),j)\n                qc.x(i)\n                for y in flip_ind:\n                    qc.x(y)\n            left -= (1<<i)\n        else:\n            flip_ind.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A1B5FFDEDE65C", "submission_order": 5, "result": "UGE", "execution_time": "1005 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n    flip_ind = []\n    left = L\n    for i in reversed(range(n)):\n        if L&(1<<i) :\n            if i == n-1:\n                qc.ry(2*math.acos(math.sqrt((1<<i)/L)),i)\n                qc.x(i)\n                for j in range(i):\n                    qc.ch(i,j)\n                qc.x(i)\n            else:\n                for y in flip_ind:\n                    qc.x(y)\n                MCMT.mcry(qc,theta=2*math.acos(math.sqrt((1<<i)/left)),q_controls=list(range(i+1,n)),q_target=i)\n                qc.x(i)\n                for j in range(i):\n                    MCMT.mcrx(qc,theta=math.pi/2,q_controls=list(range(i,n)),q_target=j)\n                    MCMT.mcrz(qc,lam=math.pi/2,q_controls=list(range(i,n)),q_target=j)\n                    MCMT.mcrx(qc,theta=math.pi/2,q_controls=list(range(i,n)),q_target=j)\n                    # qc += MCMT.mcrx(math.pi/2,list(range(i,n)),j)\n                    # qc += MCMT.mcrz(math.pi/2,list(range(i,n)),j)\n                    # qc += MCMT.mcrx(math.pi/2,list(range(i,n)),j)\n                qc.x(i)\n                for y in flip_ind:\n                    qc.x(y)\n            left -= (1<<i)\n        else:\n            flip_ind.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A1B5FFDEDE65C", "submission_order": 6, "result": "AC", "execution_time": "2135 ms", "memory": "97 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\n\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == (1<<n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n    flip_ind = []\n    left = L\n    for i in reversed(range(n)):\n        if L&(1<<i) :\n            if i == n-1:\n                qc.ry(2*math.acos(math.sqrt((1<<i)/left)),i)\n                qc.x(i)\n                for j in range(i):\n                    qc.ch(i,j)\n                qc.x(i)\n            else:\n                for y in flip_ind:\n                    qc.x(y)\n                qc.append(RYGate(2*math.acos(math.sqrt((1<<i)/left))).control(n-1-i), list(reversed(range(i,n))))\n                qc.x(i)\n                for j in range(i):\n                    qc.append(HGate().control(n-i), list(reversed(range(i,n)))+[j])\n                qc.x(i)\n                for y in flip_ind:\n                    qc.x(y)\n            left -= (1<<i)\n        else:\n            flip_ind.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A2E77FD0DDA57", "submission_order": 1, "result": "WA", "execution_time": "1100 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A2FC4372B2346", "submission_order": 1, "result": "AC", "execution_time": "1368 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve_rec(qc: QuantumCircuit, n: int, bit: int, L: int) -> None:\n    if bit < 0:\n        return\n    if L < (1<<bit):\n        qc.x(bit)\n        solve_rec(qc, n, bit-1, L)\n        qc.x(bit)\n    else:\n        qc.r(math.pi/2, 0, bit)\n        qc.mcp(-2*math.acos(math.sqrt((1<<bit)/L)), list(range(bit+1,n)), bit)\n        qc.r(-math.pi/2, 0, bit)\n        qc.x(bit)\n        for i in range(bit):\n            qc.r(math.pi/2, 0, i)\n            qc.mcp(math.pi/2, list(range(bit,n)), i)\n            qc.r(-math.pi/2, 0, i)\n        qc.x(bit)\n        solve_rec(qc, n, bit-1, L-(1<<bit))\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1 and L == 2:\n        qc.h(0)\n    if n == 1:\n        return qc\n    if L < (1<<(n-1)):\n        qc.x(n-1)\n        solve_rec(qc, n, n-2, L)\n        qc.x(n-1)\n    else:\n        qc.r(2*math.acos(math.sqrt((1<<(n-1))/L)), math.pi/2, n-1)\n        qc.x(n-1)\n        for i in range(n-1):\n            qc.ch(n-1, i)\n        qc.x(n-1)\n        solve_rec(qc, n, n-2, L-(1<<(n-1)))\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A3813AC982B39", "submission_order": 1, "result": "RE", "execution_time": "1507 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qisl\nimport math\n\ndef solve(n, l) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    target = [True]*l + [False]*(2**n-l)\n    build(n, qc, target, '')\n\n    return qc\n\ndef build(n, qc, array, prefix):\n    depth = len(prefix)\n\n    if all(array):\n        for idx in range(depth):\n            if prefix[idx] == '0':\n               qc.x(idx)\n\n        mch(qc, list(range(0, depth)), list(range(depth, n)))\n\n        for idx in range(depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n        return\n\n    half = len(array) // 2\n\n    lcount = sum(array[0:half])\n    rcount = sum(array[half:len(array)])\n\n    if rcount != 0:\n        div = math.sqrt(lcount / (lcount+rcount))\n\n        for idx in range(0, depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n        mcry(qc, -2*math.acos(div), list(range(0, depth)), [depth])\n\n        for idx in range(0, depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n    build(n, qc, array[0:half], prefix + '0')\n\n    if rcount != 0:\n        build(n, qc, array[half:len(array)], prefix + '1')\n\ndef mcry(qc, theta, control, target):\n    gate = qisl.RYGate(theta)\n    if len(control) != 0:\n        gate = gate.control(len(control))\n\n    for v in target:\n        qc.append(gate, control + [v])\n\ndef mch(qc, control, target):\n    gate = qisl.HGate().control(len(control))\n\n    for v in target:\n        qc.append(gate, control + [v])\n'''"}
{"problem": "QPC001_C2", "user": "A3813AC982B39", "submission_order": 2, "result": "WA", "execution_time": "1439 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qisl\nimport math\n\ndef solve(n, l) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    target = [True]*l + [False]*(2**n-l)\n    build(n, qc, target, '')\n\n    return qc\n\ndef build(n, qc, array, prefix):\n    depth = len(prefix)\n\n    if all(array):\n        for idx in range(depth):\n            if prefix[idx] == '0':\n               qc.x(idx)\n\n        mch(qc, list(range(0, depth)), list(range(depth, n)))\n\n        for idx in range(depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n        return\n\n    half = len(array) // 2\n\n    lcount = sum(array[0:half])\n    rcount = sum(array[half:len(array)])\n\n    if rcount != 0:\n        div = math.sqrt(lcount / (lcount+rcount))\n\n        for idx in range(0, depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n        mcry(qc, 2*math.acos(div), list(range(0, depth)), [depth])\n\n        for idx in range(0, depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n    build(n, qc, array[0:half], prefix + '0')\n\n    if rcount != 0:\n        build(n, qc, array[half:len(array)], prefix + '1')\n\ndef mcry(qc, theta, control, target):\n    gate = qisl.RYGate(theta)\n    if len(control) != 0:\n        gate = gate.control(len(control))\n\n    for v in target:\n        qc.append(gate, control + [v])\n\ndef mch(qc, control, target):\n    gate = qisl.HGate()\n    if len(control) != 0:\n        gate = gate.control(len(control))\n\n    for v in target:\n        qc.append(gate, control + [v])\n'''"}
{"problem": "QPC001_C2", "user": "A3813AC982B39", "submission_order": 3, "result": "AC", "execution_time": "4455 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qisl\nimport math\n\ndef solve(n, l) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    target = [True]*l + [False]*(2**n-l)\n    build(n, qc, target, '')\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n - 1 - idx)\n\n    return qc\n\ndef build(n, qc, array, prefix):\n    depth = len(prefix)\n\n    if all(array):\n        for idx in range(depth):\n            if prefix[idx] == '0':\n               qc.x(idx)\n\n        mch(qc, list(range(0, depth)), list(range(depth, n)))\n\n        for idx in range(depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n        return\n\n    half = len(array) // 2\n\n    lcount = sum(array[0:half])\n    rcount = sum(array[half:len(array)])\n\n    if rcount != 0:\n        div = math.sqrt(lcount / (lcount+rcount))\n\n        for idx in range(0, depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n        mcry(qc, 2*math.acos(div), list(range(0, depth)), [depth])\n\n        for idx in range(0, depth):\n            if prefix[idx] == '0':\n                qc.x(idx)\n\n    build(n, qc, array[0:half], prefix + '0')\n\n    if rcount != 0:\n        build(n, qc, array[half:len(array)], prefix + '1')\n\ndef mcry(qc, theta, control, target):\n    gate = qisl.RYGate(theta)\n    if len(control) != 0:\n        gate = gate.control(len(control))\n\n    for v in target:\n        qc.append(gate, control + [v])\n\ndef mch(qc, control, target):\n    gate = qisl.HGate()\n    if len(control) != 0:\n        gate = gate.control(len(control))\n\n    for v in target:\n        qc.append(gate, control + [v])\n'''"}
{"problem": "QPC001_C2", "user": "A3B429A049062", "submission_order": 1, "result": "AC", "execution_time": "2320 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if L==1:\n        return qc\n    if n==1:\n        qc.h(0)\n        return qc\n    MX = L-1\n    bit_position = []\n    for i in range(n):\n        if (MX>>i)&1:\n            bit_position.append(i)\n    bit_position.reverse()\n    # print(bit_position)\n    sz = L\n    for i in range(len(bit_position)):\n        pos = bit_position[i]\n        prob = (1<<pos)/sz\n        # print(pos, prob, sz, 1<<pos)\n        theta = math.acos(math.sqrt(prob))\n        if i == 0:\n            qc.ry(2.0 * theta,pos)\n        else:\n            qc.cry(2.0 * theta,bit_position[i-1],pos)\n        sz -= (1<<pos)\n\n    bit_position.reverse()\n    for i in range(len(bit_position)-1):\n        pos = bit_position[i]\n        if pos == 0:\n            continue\n        custom = HGate().control(2,ctrl_state=\"10\")\n        for j in range(pos):\n            qc.append(custom,[pos,bit_position[i+1],j])\n    if bit_position[-1] != 0:\n        qc.ch(bit_position[-1],range(bit_position[-1]),ctrl_state=0)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A43F46784ACE5", "submission_order": 1, "result": "WA", "execution_time": "1458 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A43F46784ACE5", "submission_order": 2, "result": "TLE", "execution_time": "6000 ms", "memory": "512 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom qiskit.circuit.library import HGate\nfrom qiskit.circuit.library import YGate\nfrom qiskit.circuit.library import RYGate\n\n\n\"\"\"\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit import transpile\nfrom qiskit.circuit.library import RealAmplitudes\nfrom qiskit.quantum_info import SparsePauliOp\nfrom qiskit_aer import AerSimulator\nfrom qiskit import QuantumCircuit\nfrom qiskit.visualization import plot_histogram, plot_state_city\n\n\ndef debug(qc):\n    qc.save_statevector()\n    simulator = AerSimulator(method='statevector')\n    circ = transpile(qc, simulator)\n    result = simulator.run(circ).result()\n    statevector = result.get_statevector(circ)\n    # plot_state_city(statevector, title='Bell state', filename='statevector.png')\n    print(statevector)\n\"\"\"\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L -= 1\n    src = 0\n    ## [src] が非零\n    ## [0, src) が完成\n    ## 1点 src だけ係数未完成\n    for i in range(n):\n        qc.x(i)\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            theta = 2 * math.atan2(math.sqrt(1 + (L & ((1 << i) - 1))), math.sqrt(1 << i))\n            if n == 1:\n                qc.ry(theta, i)\n            else:\n                qc.append(RYGate(theta).control(n - 1), [k for k in range(n) if k != i] + [i])\n            for j in range(i):\n                qc.append(HGate().control(n - i), list(range(i, n)) + [j])\n            qc.x(i)\n\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    print(qc.depth())\n    return qc\n\n\nsolve(10, 1023)\n'''"}
{"problem": "QPC001_C2", "user": "A43F46784ACE5", "submission_order": 3, "result": "TLE", "execution_time": "6000 ms", "memory": "149 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom qiskit.circuit.library import HGate\nfrom qiskit.circuit.library import YGate\nfrom qiskit.circuit.library import RYGate\n\n\n\"\"\"\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit import transpile\nfrom qiskit.circuit.library import RealAmplitudes\nfrom qiskit.quantum_info import SparsePauliOp\nfrom qiskit_aer import AerSimulator\nfrom qiskit import QuantumCircuit\nfrom qiskit.visualization import plot_histogram, plot_state_city\n\n\ndef debug(qc):\n    qc.save_statevector()\n    simulator = AerSimulator(method='statevector')\n    circ = transpile(qc, simulator)\n    result = simulator.run(circ).result()\n    statevector = result.get_statevector(circ)\n    # plot_state_city(statevector, title='Bell state', filename='statevector.png')\n    print(statevector)\n\"\"\"\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L -= 1\n    src = 0\n    ## [src] が非零\n    ## [0, src) が完成\n    ## 1点 src だけ係数未完成\n    for i in range(n):\n        qc.x(i)\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            theta = 2 * math.atan2(math.sqrt(1 + (L & ((1 << i) - 1))), math.sqrt(1 << i))\n            if n == 1:\n                qc.ry(theta, i)\n            else:\n                qc.append(RYGate(theta).control(n - 1), [k for k in range(n) if k != i] + [i])\n            for j in range(i):\n                qc.append(HGate().control(n - i), list(range(i, n)) + [j])\n            qc.x(i)\n\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    print(qc.depth())\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A43F46784ACE5", "submission_order": 4, "result": "TLE", "execution_time": "6000 ms", "memory": "148 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom qiskit.circuit.library import HGate\nfrom qiskit.circuit.library import YGate\nfrom qiskit.circuit.library import RYGate\n\n\n\"\"\"\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit import transpile\nfrom qiskit.circuit.library import RealAmplitudes\nfrom qiskit.quantum_info import SparsePauliOp\nfrom qiskit_aer import AerSimulator\nfrom qiskit import QuantumCircuit\nfrom qiskit.visualization import plot_histogram, plot_state_city\n\n\ndef debug(qc):\n    qc.save_statevector()\n    simulator = AerSimulator(method='statevector')\n    circ = transpile(qc, simulator)\n    result = simulator.run(circ).result()\n    statevector = result.get_statevector(circ)\n    # plot_state_city(statevector, title='Bell state', filename='statevector.png')\n    print(statevector)\n\"\"\"\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L -= 1\n    src = 0\n    ## [src] が非零\n    ## [0, src) が完成\n    ## 1点 src だけ係数未完成\n    for i in range(n):\n        qc.x(i)\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            theta = 2 * math.atan2(math.sqrt(1 + (L & ((1 << i) - 1))), math.sqrt(1 << i))\n            if n == 1:\n                qc.ry(theta, i)\n            else:\n                qc.append(RYGate(theta).control(n - 1), [k for k in range(n) if k != i] + [i])\n            for j in range(i):\n                qc.append(HGate().control(n - i), list(range(i, n)) + [j])\n            qc.x(i)\n\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A43F46784ACE5", "submission_order": 5, "result": "TLE", "execution_time": "6000 ms", "memory": "148 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n#from qiskit.circuit.library import ZGate\nfrom qiskit.circuit.library import HGate\n#from qiskit.circuit.library import YGate\nfrom qiskit.circuit.library import RYGate\n\n\n\"\"\"\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit import transpile\nfrom qiskit.circuit.library import RealAmplitudes\nfrom qiskit.quantum_info import SparsePauliOp\nfrom qiskit_aer import AerSimulator\nfrom qiskit import QuantumCircuit\nfrom qiskit.visualization import plot_histogram, plot_state_city\n\n\ndef debug(qc):\n    qc.save_statevector()\n    simulator = AerSimulator(method='statevector')\n    circ = transpile(qc, simulator)\n    result = simulator.run(circ).result()\n    statevector = result.get_statevector(circ)\n    # plot_state_city(statevector, title='Bell state', filename='statevector.png')\n    print(statevector)\n\"\"\"\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L -= 1\n    src = 0\n    ## [src] が非零\n    ## [0, src) が完成\n    ## 1点 src だけ係数未完成\n    for i in range(n):\n        qc.x(i)\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            theta = 2 * math.atan2(math.sqrt(1 + (L & ((1 << i) - 1))), math.sqrt(1 << i))\n            if n == 1:\n                qc.ry(theta, i)\n            else:\n                qc.append(RYGate(theta).control(n - 1), [k for k in range(n) if k != i] + [i])\n            for j in range(i):\n                qc.append(HGate().control(n - i), list(range(i, n)) + [j])\n            qc.x(i)\n\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A43F46784ACE5", "submission_order": 6, "result": "TLE", "execution_time": "6000 ms", "memory": "147 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n#from qiskit.circuit.library import ZGate\nfrom qiskit.circuit.library import HGate\n#from qiskit.circuit.library import YGate\nfrom qiskit.circuit.library import RYGate\n\n\n\"\"\"\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit import transpile\nfrom qiskit.circuit.library import RealAmplitudes\nfrom qiskit.quantum_info import SparsePauliOp\nfrom qiskit_aer import AerSimulator\nfrom qiskit import QuantumCircuit\nfrom qiskit.visualization import plot_histogram, plot_state_city\n\n\ndef debug(qc):\n    qc.save_statevector()\n    simulator = AerSimulator(method='statevector')\n    circ = transpile(qc, simulator)\n    result = simulator.run(circ).result()\n    statevector = result.get_statevector(circ)\n    # plot_state_city(statevector, title='Bell state', filename='statevector.png')\n    print(statevector)\n\"\"\"\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L -= 1\n    src = 0\n    ## [src] が非零\n    ## [0, src) が完成\n    ## 1点 src だけ係数未完成\n    for i in range(n):\n        qc.x(i)\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            theta = 2 * math.atan2(math.sqrt(1 + (L & ((1 << i) - 1))), math.sqrt(1 << i))\n            if n == 1:\n                qc.ry(theta, i)\n            else:\n                qc.append(RYGate(theta).control(n - 1), [k for k in range(n) if k != i] + [i])\n            for j in range(i):\n                qc.append(HGate().control(n - i), list(range(i, n)) + [j])\n            qc.x(i)\n\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A43F46784ACE5", "submission_order": 7, "result": "TLE", "execution_time": "6000 ms", "memory": "148 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\nfrom qiskit.circuit.library import RYGate\n\n\n\"\"\"\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit import transpile\nfrom qiskit.circuit.library import RealAmplitudes\nfrom qiskit.quantum_info import SparsePauliOp\nfrom qiskit_aer import AerSimulator\nfrom qiskit import QuantumCircuit\nfrom qiskit.visualization import plot_histogram, plot_state_city\n\n\ndef debug(qc):\n    qc.save_statevector()\n    simulator = AerSimulator(method='statevector')\n    circ = transpile(qc, simulator)\n    result = simulator.run(circ).result()\n    statevector = result.get_statevector(circ)\n    # plot_state_city(statevector, title='Bell state', filename='statevector.png')\n    print(statevector)\n\"\"\"\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L -= 1\n    src = 0\n    ## [src] が非零\n    ## [0, src) が完成\n    ## 1点 src だけ係数未完成\n    for i in range(n):\n        qc.x(i)\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            theta = 2 * math.atan2(math.sqrt(1 + (L & ((1 << i) - 1))), math.sqrt(1 << i))\n            if n == 1 or n == i + 1:\n                qc.ry(theta, i)\n            else:\n                qc.append(RYGate(theta).control(n - i - 1), list(range(i + 1, n)) + [i])\n            for j in range(i):\n                qc.append(HGate().control(n - i), list(range(i, n)) + [j])\n            qc.x(i)\n\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A45DB8C1A90A1", "submission_order": 1, "result": "AC", "execution_time": "3897 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n\n    for i in reversed(range(n)):\n        if bits[i] == 0:\n            continue\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if bits[j] == 0:\n                qc.x(j)\n\n    return qc\n\ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n    qc.x(range(n))\n    return qc\n\ndef U(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(max(1, math.ceil(math.log2(L)))))\n    return qc\n\ndef Um(n: int, L: int, m: int, u: QuantumCircuit, r_t: QuantumCircuit, r_s: QuantumCircuit) -> QuantumCircuit:\n    if m == 0:\n        return U(n, L)\n    u_m_1 = Um(n, L, m - 1, u, r_t, r_s)\n    return u_m_1.compose(r_t).compose(u_m_1.inverse()).compose(r_s).compose(u_m_1)\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    u = U(n, L)\n    r_t = Rt(n, L)\n    r_s = Rs(n)\n    um = Um(n, L, 2, u, r_t, r_s)\n    return um\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 1, "result": "WA", "execution_time": "1004 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\n        \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    itr = 0\n    for i in range(n):\n        if L > (1 << i):\n            itr = i\n            qc.h(i)\n\n    loop_count = -1\n    for p in range(100):\n        expected = math.sin((2 * loop_count + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (itr+1)))) ** 2\n        if expected > 0.996:\n            loop_count = p\n            break\n        \n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n            \n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n        \n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n        \n        qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 2, "result": "WA", "execution_time": "1020 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\n        \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    itr = 0\n    for i in range(n):\n        if L > (1 << i):\n            itr = i\n            qc.h(i)\n\n    loop_count = -1\n    for p in range(1000):\n        expected = math.sin((2 * loop_count + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (itr+1)))) ** 2\n        if expected > 0.998:\n            loop_count = p\n            break\n        \n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n            \n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n        \n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n        \n        qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 3, "result": "RE", "execution_time": "795 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\n        \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    itr = 0\n    for i in range(n):\n        if L > (1 << i):\n            itr = i\n            qc.h(i)\n\n    loop_count = -1\n    for p in range(1000):\n        loop_count = p\n        expected = math.sin((2 * loop_count + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (itr+1)))) ** 2\n        if expected > 0.998:\n            loop_count = p\n            break\n        \n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n            \n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n        \n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n        \n        qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 4, "result": "WA", "execution_time": "873 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\n        \ndef solve(n: int, L: int) -> QuantumCircuit:\n\n    qc = QuantumCircuit(n)\n    target_itr = 0\n    for i in range(n):\n        if L >= (1 << i):\n            target_itr = i + 1\n\n    loop_count = -1\n    itr = -1\n    for p in range(1000):\n        for qubit in range(target_itr, n):\n            expected = math.sin((2 * p + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (qubit)))) ** 2\n            if expected >= 0.996:\n                loop_count = p\n                itr = qubit - 1\n                break\n        if loop_count != -1:\n            break\n\n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n\n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n\n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n\n        qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 5, "result": "WA", "execution_time": "900 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n\n    qc = QuantumCircuit(n)\n    target_itr = 0\n    for i in range(n):\n        if L >= (1 << i):\n            target_itr = i + 1\n\n    loop_count = -1\n    itr = -1\n    for p in range(1000):\n        for qubit in range(target_itr, n):\n            expected = math.sin((2 * p + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (qubit)))) ** 2\n            if expected >= 0.996:\n                loop_count = p\n                itr = qubit - 1\n                break\n        if loop_count != -1:\n            break\n\n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n\n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n\n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n\n        qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 6, "result": "RE", "execution_time": "1496 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    itr = 0\n    for i in range(n):\n        if L > (1 << i):\n            itr = i\n            qc.h(i)\n\n    loop_count = -1\n    for p in range(1000):\n        loop_count = p\n        expected = math.sin((2 * loop_count + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (itr+1)))) ** 2\n        if expected > 0.995:\n            loop_count = p\n            break\n        \n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n            \n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n        \n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n        \n        qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 7, "result": "RE", "execution_time": "941 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\n        \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1 or L ==1:\n        return qc\n    itr = 1\n    for i in range(n):\n        if L >= (1 << i) or True:\n            itr = n-1\n            qc.h(i)\n\n    loop_count = -1\n    for i in range(1000):\n        expected = math.sin((2 * i + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (itr+1)))) ** 2\n        if expected > 0.995:\n            loop_count = i\n            break\n\n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n            \n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n        \n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n        if itr == 0:\n            qc.z(0)\n        else:\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    results = execute(qc, backend=Aer.get_backend('statevector_simulator'), shots=1).result()\n    data = results.get_statevector()\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 8, "result": "WA", "execution_time": "893 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\n        \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1 or L ==1:\n        return qc\n    itr = 1\n    for i in range(n):\n        if L >= (1 << i) or True:\n            itr = n-1\n            qc.h(i)\n\n    loop_count = -1\n    for i in range(1000):\n        expected = math.sin((2 * i + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (itr+1)))) ** 2\n        if expected > 0.995:\n            loop_count = i\n            break\n\n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n            \n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n        \n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n        if itr == 0:\n            qc.z(0)\n        else:\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    #results = execute(qc, backend=Aer.get_backend('statevector_simulator'), shots=1).result()\n    #data = results.get_statevector()\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A49A1EC282349", "submission_order": 9, "result": "WA", "execution_time": "1032 ms", "memory": "92 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef oracle(qc: QuantumCircuit, n:int, L:int):\n\n    if (L & (1 << (n-1))) == 0:\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n\n    for i in range(n-2, -1,-1):\n        b = (L & (1  << i))\n        if b == 0:\n            qc.x(i)\n        else:\n            data = []\n            for t in range(n-1,i,-1):\n                data.append(t)\n            qc.x(i)\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=i)\n            qc.x(i)\n\n    for i in range(n):\n        if(L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\n        \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1 or L ==1:\n        return qc\n    itr = 1\n    for i in range(n):\n        if L >= (1 << i) or True:\n            itr = n-1\n            qc.h(i)\n\n    loop_count = -1\n    for i in range(10000):\n        expected = math.sin((2 * i + 1) * math.asin(math.sqrt(L) / math.sqrt(1 << (itr+1)))) ** 2\n        if expected > 0.995:\n            loop_count = i\n            break\n\n    # grover loop\n    for t in range(loop_count):\n        qc = oracle(qc,itr+1,L)\n        for p in range(itr + 1):\n            qc.h(p)\n            \n        qc.rz(math.pi * 2,0)\n        for t in range(itr + 1):\n            qc.x(t)\n        \n        data = []\n        for t in range(itr):\n            data.append(itr - t)\n        if itr == 0:\n            qc.z(0)\n        else:\n            qc.mcp(lam=math.pi,control_qubits=data, target_qubit=0)\n        for t in range(itr + 1):\n            qc.x(t)\n        for p in range(itr + 1):\n            qc.h(p)\n    #results = execute(qc, backend=Aer.get_backend('statevector_simulator'), shots=1).result()\n    #data = results.get_statevector()\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A4D2C11FDA395", "submission_order": 1, "result": "RE", "execution_time": "1038 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef prepare_uniform_superposition(qc, n, L):\n    # We need to apply Hadamard gates to create a uniform superposition.\n    # However, we don't want to apply it to all qubits if L is not a power of 2.\n    for i in range(n):\n        if L > 1 << i:\n            qc.h(i)\n    \n    # If L is not a power of 2, we need to correct the amplitudes.\n    if not math.isclose(L, 2 ** round(math.log2(L))):\n        angle = 2 * math.acos(math.sqrt(L / 2 ** n))\n        for i in range(n):\n            # Apply controlled rotation to correct the amplitude of states that are not part of the L states\n            qc.cu(angle, 0, 0, 0, i, range(i+1, n))\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    prepare_uniform_superposition(qc, n, L)\n    return qc\n\n# Example usage:\nn = 3\nL = 3\nqc = solve(n, L)\nprint(qc)\n'''"}
{"problem": "QPC001_C2", "user": "A4D2C11FDA395", "submission_order": 2, "result": "RE", "execution_time": "992 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef prepare_uniform_superposition(qc, n, L):\n    # We need to apply Hadamard gates to create a uniform superposition.\n    # However, we don't want to apply it to all qubits if L is not a power of 2.\n    for i in range(n):\n        if L > 1 << i:\n            qc.h(i)\n    \n    # If L is not a power of 2, we need to correct the amplitudes.\n    if not math.isclose(L, 2 ** round(math.log2(L))):\n        angle = 2 * math.acos(math.sqrt(L / 2 ** n))\n        for i in range(n):\n            # Apply controlled rotation to correct the amplitude of states that are not part of the L states\n            qc.cu(angle, 0, 0, 0, i, range(i+1, n))\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    prepare_uniform_superposition(qc, n, L)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A51FBC38E86F4", "submission_order": 1, "result": "TOE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef Rt(n:int,L:int)->QuantumCircuit\n    qc=QuantumCircuit(n)\n    for i in range(n):\n        if not (L>>i)&1:\n            continue\n        for j in range(i+1,n):\n            if not (L>>j)&1:\n                qc.x(j)\n        qc.x(i)\n        if i==n-:\n            qc.p(math.pi/3,i)\n        else:\n            qc.append(PhaseGate(math.pi/3).control(n-i-1),range(i,n))\n        qc.x(i)\n        for j in range(i+1,n):\n            if not (L>>j)&1:\n                qc.x(j)\n    return qc\n\ndef Rs(n:int)->QuantumCircuit:\n    qc=QuantumCircuit(n)\n    qc.x(range(n))\n    if n==1:\n        qc.p(math.pi/3,0)\n    else:\n        qc.append(PhaseGate(math.pi/3).control(n-1),range(n))\n\n    qc.x(range(n))\n\n    return qc\n\ndef U(m:int,n:int,L:int)->QuantumCircuit:\n    qc=QuantumCircuit(n)\n\n    if m==0:\n        qc.h(range(m))\n        return qc\n\n    u=U(m-1,n,L)\n\n    qc.compose(u,inplace=True)\n    qc.compose(Rt(n,L),inplace=True)\n    qc.compose(u.inverse(),inplace=True)\n    qc.compose(Rs(n),inplace=True)\n    qc.compose(u,inplace=True)\n\n    return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    k=math.ceil(math.log2(L))\n    if k==0:\n        return qc\n    m=2\n    qc.compose(U(m,k,L),inplace=True)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A555E99E9F317", "submission_order": 1, "result": "AC", "execution_time": "2355 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import ZGate,XGate,RYGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n\n    # Write your code here:\n    \n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 - start), range(start,qubits))\n        else:\n            qc.z(start)\n\n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    d={}\n    for i in range(1<<n):\n        tmp=\"\"\n        for j in bin(i)[2:].rjust(n,\"0\"):\n            tmp+=j\n            d.setdefault(tmp,0)\n\n    for i in range(L):\n        s=bin(i)[2:].rjust(n,\"0\")\n        tmp=\"\"\n        for i in s:\n            tmp+=i\n            d[tmp]+=1\n\n    # 指定したbit(ゼロ状態)が0になる確率をratioにする\n\n    # 指定したcontroll bitがすべて1の場合にbit(ゼロ状態)が0になる確率をratioにする    \n    def crotate(qc,bits,p0):\n        theta=math.acos(p0*2-1)\n        if len(bits)==1:\n            qc.ry(theta,bits[0])\n        else:\n            qc.append(RYGate(theta).control(len(bits)-1),bits)\n\n    \n    def dfs(prefix,bit,qc,n):\n        # print(\"call\",prefix,bit)\n        prefix0=prefix+\"0\"\n        prefix1=prefix+\"1\"\n        v=int(prefix.ljust(n,\"0\"),2)\n\n\n        if bit==-1 or d.get(prefix0)+d.get(prefix1)==0:return\n        if prefix==\"\":\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            to_calcable(n,qc,v,0)\n            crotate(qc,[bit],p0)\n            to_calcable(n,qc,v,0)\n            dfs(prefix0,bit-1,qc,n)\n            dfs(prefix1,bit-1,qc,n)\n        elif bit>=0:\n            # print(prefix,d[prefix+\"0\"],d[prefix+\"1\"])\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            if p0==0.5:\n                to_calcable(n,qc,v,0)\n                for b in range(bit,-1,-1):\n                    crotate(qc,list(range(n-1,bit,-1))+[b],p0)\n                to_calcable(n,qc,v,0)\n            else:\n                to_calcable(n,qc,v,0)\n                crotate(qc,list(range(n-1,bit-1,-1)),p0)\n                to_calcable(n,qc,v,0)\n                dfs(prefix0,bit-1,qc,n)\n                dfs(prefix1,bit-1,qc,n)\n\n    dfs(\"\",n-1,qc,n)\n    # depth = qc.depth()\n    # print(\"量子回路の深さ:\", depth)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A5894F5B7B849", "submission_order": 1, "result": "AC", "execution_time": "2192 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, HGate, RYGate\nfrom math import sqrt, acos, pi\n\ndef append_control_gate(qc: QuantumCircuit, gate, target_qubit: int, ctrl_state: int, controlled_qubits)->QuantumCircuit:\n\tif len(controlled_qubits) == 0:\n\t\tqc.append(gate, [target_qubit])\n\telse:\n\t\tqc.append(gate.control(len(controlled_qubits), ctrl_state = ctrl_state), controlled_qubits + [target_qubit])\n\treturn qc\n\ndef solve(n: int, L: int)->QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tif L == (1 << n):\n\t\tfor i in range(n):\n\t\t\tqc.h(i)\n\t\treturn qc\n\tmask = (1 << n) - 1\n\tctrl_state = 0\n\tcontrolled_qubits = []\n\tfor bit in range(n - 1, -1, -1):\n\t\tif L >> bit & 1:\n\t\t\tleft, right = 1 << bit, L - (1 << bit)\n\t\t\ttheta = acos(sqrt(left) / sqrt(left + right)) * 2\n\t\t\tappend_control_gate(qc, RYGate(theta), bit, ctrl_state, controlled_qubits)\n\t\t\tfor bit_next in range(bit - 1, -1, -1):\n\t\t\t\tappend_control_gate(qc, HGate(), bit_next, ctrl_state, controlled_qubits + [bit])\n\t\t\tL ^= 1 << bit\n\t\t\tctrl_state |= 1 << len(controlled_qubits)\n\t\tcontrolled_qubits += [bit]\n\treturn qc\n'''"}
{"problem": "QPC001_C2", "user": "A5B265919F8E0", "submission_order": 1, "result": "DLE", "execution_time": "3000 ms", "memory": "178 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate, XGate\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Prepare an n-qubit state such that |0>,|1>,...,|L-1> have equal\n    probability amplitudes and the total probability of these states\n    is (ideally) 1.  The construction is exact – amplitudes of all\n    states i >= L are 0 – therefore the success probability certainly\n    exceeds 1-5e-3.\n    \"\"\"\n    qc = QuantumCircuit(n)\n\n    # -----------------------------------------------------------------\n    #  Helper routines\n    # -----------------------------------------------------------------\n    def apply_controlled_ry(theta: float, target: int, ctrl_bits):\n        \"\"\"\n        Apply RY(theta) to `target` qubit, controlled on the qubits\n        in `ctrl_bits`.  `ctrl_bits` is a list of tuples\n        (qubit_index , value) where value is 0 or 1, telling whether\n        we condition on |0> or |1>.  If value == 0 we surround the\n        control qubit with X gates.\n        \"\"\"\n        pre_x = []\n        controls = []\n\n        # turn controls that should be in |0> into |1> by X, remember them\n        for q, val in ctrl_bits:\n            if val == 0:\n                qc.x(q)\n                pre_x.append(q)\n            controls.append(q)\n\n        if len(controls) == 0:\n            qc.ry(theta, target)\n        else:\n            gate = RYGate(theta).control(len(controls))\n            qc.append(gate, controls + [target])\n\n        # restore the negated control qubits\n        for q in reversed(pre_x):\n            qc.x(q)\n\n    def apply_force_one(target: int, ctrl_bits):\n        \"\"\"\n        Deterministically set `target` qubit to |1> on the sub-space\n        specified by `ctrl_bits` (same format as above).\n        Implemented with a multi-controlled X.\n        \"\"\"\n        pre_x = []\n        controls = []\n        for q, val in ctrl_bits:\n            if val == 0:\n                qc.x(q)\n                pre_x.append(q)\n            controls.append(q)\n\n        if len(controls) == 0:\n            qc.x(target)\n        else:\n            gate = XGate().control(len(controls))\n            qc.append(gate, controls + [target])\n\n        for q in reversed(pre_x):\n            qc.x(q)\n\n    # -----------------------------------------------------------------\n    #  Recursive construction\n    # -----------------------------------------------------------------\n    selected = list(range(L))                      # indices that must get weight\n    qubits_order = list(range(n))                  # use little-endian: 0 (LSB) … n-1 (MSB)\n\n    def build(indices, bit_pos, ctrl_bits):\n        \"\"\"\n        `indices` : list of basis indices still to realise\n        `bit_pos` : current qubit to branch on (0 … n-1)\n        `ctrl_bits` : list of previously fixed qubits (for controls)\n        \"\"\"\n        if len(indices) <= 1 or bit_pos >= n:\n            # Either a single state left or no more qubits to process.\n            if len(indices) == 1:\n                target_state = indices[0]\n                # If the remaining qubit (bit_pos) values have to be 1,\n                # set them explicitly.\n                for b in range(bit_pos, n):\n                    desired = (target_state >> b) & 1\n                    if desired == 1:\n                        apply_force_one(b, ctrl_bits)\n            return\n\n        target_qubit = qubits_order[bit_pos]\n        zero_branch = [i for i in indices if ((i >> bit_pos) & 1) == 0]\n        one_branch  = [i for i in indices if ((i >> bit_pos) & 1) == 1]\n\n        if len(zero_branch) == 0:\n            # All states require this qubit to be |1>\n            apply_force_one(target_qubit, ctrl_bits)\n        elif len(one_branch) == 0:\n            # All states require |0>, nothing to do\n            pass\n        else:\n            # Both 0 and 1 appear – split amplitudes accordingly\n            theta = 2 * math.atan2(math.sqrt(len(one_branch)),\n                                   math.sqrt(len(zero_branch)))\n            apply_controlled_ry(theta, target_qubit, ctrl_bits)\n\n        # Recurse on the sub-branches\n        if len(zero_branch) > 0:\n            build(zero_branch, bit_pos + 1, ctrl_bits + [(target_qubit, 0)])\n        if len(one_branch) > 0:\n            build(one_branch,  bit_pos + 1, ctrl_bits + [(target_qubit, 1)])\n\n    # -----------------------------------------------------------------\n    #  Kick-off the recursion\n    # -----------------------------------------------------------------\n    if L > 0:\n        build(selected, 0, [])\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A5B265919F8E0", "submission_order": 2, "result": "UGE", "execution_time": "2004 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nimport numpy as np\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Returns a QuantumCircuit acting on `n` qubits that prepares the state\n        |ψ> = (1/√L) Σ_{i=0}^{L-1} |i>\n    with little-endian integer encoding.\n\n    The construction keeps the circuit depth low by\n      • using simple Hadamards when L is a power of two;\n      • otherwise employing `initialize` only on the minimum number of qubits\n        needed (m = ⌈log₂ L⌉), leaving the remaining qubits in |0>.\n    \"\"\"\n    qc = QuantumCircuit(n)\n\n    # Trivial case  ───────\n    if L == 1:\n        # The initial |0⋯0⟩ is already the desired state.\n        return qc\n\n    # Power-of-two case  ──\n    if (L & (L - 1)) == 0:          # checks if L is a power of two\n        k = int(math.log2(L))       # number of qubits that need Hadamards\n        for qubit in range(k):      # apply to least-significant qubits\n            qc.h(qubit)\n        return qc\n\n    # General case  ───────\n    # Work only on m = ⌈log₂ L⌉ least-significant qubits.\n    m = math.ceil(math.log2(L))\n    vec_len = 1 << m                # 2**m\n    state_vec = np.zeros(vec_len, dtype=complex)\n    amplitude = 1 / math.sqrt(L)\n    state_vec[:L] = amplitude       # equal amplitudes for |0⟩ … |L-1⟩\n\n    # Initialize those m qubits; higher qubits remain in |0⟩.\n    target_qubits = list(range(m))  # little-endian ordering\n    qc.initialize(state_vec, target_qubits)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A5B265919F8E0", "submission_order": 3, "result": "RE", "execution_time": "1682 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\nimport math\nimport numpy as np\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Return a circuit that prepares (up to global phase)\n\n        |ψ⟩ = 1/√L · Σ_{k=0}^{L-1} |k⟩_little-endian\n\n    on an n-qubit register, with total depth ≤ 1000 for every\n    (n ≤ 10, 1 ≤ L ≤ 2^n).\n\n    Strategy\n    --------\n    •  If  L  is a power of two, apply Hadamards to the\n       lowest  log₂(L)  qubits – finished (depth = 1).\n\n    •  Otherwise, write  L = 2^m + r  with 0 < r < 2^m.\n       Use qubit  m  as a “flag”:\n\n          |0⟩⊗|u_{2^m}⟩   (2^m states)\n                   ──┐\n          |1⟩⊗|u_{r}⟩    (r   states)\n\n       where  |u_t⟩  is the uniform superposition of  t\n       computational-basis states.\n\n       Preparation steps\n       1)  R_y(θ) on the flag with\n              tan(θ/2) = √(r / 2^m)\n           sets the correct weight ratio between the two\n           branches so that every populated basis state\n           finally has amplitude 1/√L.\n\n       2)  Put the first  m  qubits into |u_{2^m}⟩ with a\n           layer of Hadamards (depth +1).\n\n       3)  For flag = 1 we undo those Hadamards (controlled-H,\n           one per qubit) so that the branch is back in\n           |0…0⟩_m.\n\n       4)  If  r > 1 we attach a controlled “initialize”\n           gate that turns |0…0⟩ into |u_r⟩ on the first m\n           qubits.  The initialise acts on ≤ 9 qubits\n           (m ≤ 9) so its decomposed depth is ≤ 510;\n           overall circuit depth stays well below 1000.\n\n       Remaining (unused) qubits, if any, stay in |0⟩,\n       hence contribute only zero amplitudes.\n\n    All gates are taken from the permitted standard gate set.\n    \"\"\"\n    qc = QuantumCircuit(n)\n\n    # Trivial case -----------------------------------------------------------\n    if L == 1:\n        # Already in |0…0>, nothing to do.\n        return qc\n\n    # Power-of-two case ------------------------------------------------------\n    if (L & (L - 1)) == 0:\n        k = int(math.log2(L))          # number of Hadamards needed\n        for q in range(k):\n            qc.h(q)\n        return qc\n\n    # General case  L = 2^m + r  (0 < r < 2^m) ------------------------------\n    m = int(math.floor(math.log2(L)))  # largest power-of-two exponent\n    base = 1 << m                      # 2^m\n    r = L - base                       # remainder  (1 … 2^m - 1)\n    flag = m                           # use qubit m as the flag\n\n    # 1. amplitude ratio between the two branches\n    theta = 2 * math.atan(math.sqrt(r / base))\n    qc.ry(theta, flag)\n\n    # 2. make the |0>-flag branch uniform over 2^m states\n    for q in range(m):\n        qc.h(q)\n\n    # 3. for flag = 1, revert those Hadamards (H is its own inverse)\n    ch_gate = HGate().control(1)\n    for q in range(m):\n        qc.append(ch_gate, [flag, q])\n\n    # 4. prepare |u_r> when flag = 1   (skip if r == 1, because the\n    #    branch is already |0…0>)\n    if r > 1:\n        vec = np.zeros(base, dtype=complex)\n        vec[:r] = 1 / math.sqrt(r)     # amplitudes for |0>…|r-1>\n        prep = QuantumCircuit(m)\n        prep.initialize(vec, list(range(m)))\n        cprep = prep.to_gate().control(1)\n        qc.append(cprep, [flag] + list(range(m)))\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A5F7EA0E472A9", "submission_order": 1, "result": "AC", "execution_time": "2535 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\ndef get_bit(x, y):\n    return 1 if x & int(2 ** y) != 0 else 0\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    M = L\n    # Write your code here:\n    ls = [i for i in range(n) if get_bit(M, i)]\n    if len(ls) == 0:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    for l in ls[1:]:\n        qc.x(l)\n\n    l0 = ls[0]\n    if len(ls) == 1:\n        print(l0)\n        for i in range(l0):\n            qc.h(i)\n        return qc\n    \n    l1 = ls[1]\n    M0 = 2 ** l0\n    if l0 > 0:\n        for i in range(l0):\n            qc.h(i)\n    theta0 = -2 * acos(sqrt(M0 / M))\n    qc.ry(theta0, l1)\n\n    qc.x(l1)\n    for i in range(l0, l1):\n        qc.ch(l1, i)\n    qc.x(l1)\n\n    k = len(ls) - 1\n\n    Mm = M0\n\n    for m in range(1, k):\n        theta_m = -2 * acos(sqrt(2 ** ls[m] / (M - Mm)))\n        qc.x(ls[m])\n        qc.cry(theta_m, ls[m], ls[m+1])\n        qc.x(ls[m])\n        qc.x(ls[m+1])\n        for i in range(ls[m], ls[m+1]):\n            qc.ch(ls[m+1], i)\n        qc.x(ls[m+1])\n        Mm = Mm + 2 ** ls[m]\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A63FF8416C913", "submission_order": 1, "result": "AC", "execution_time": "2150 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    lis = []\n    k = L\n    tmp = 0\n    while(k>0):\n        if k%2:\n            lis = lis + [tmp]\n        tmp += 1\n        k = k //2\n    m = 2 ** (lis[0])\n    if len(lis) == 1:\n        for i in range(lis[0]):\n            qc.h(i)\n        return qc\n    \n    for i in range(1,len(lis)):\n        qc.x(lis[i])\n    if lis[0] > 0:\n        for i in range(lis[0]):\n            qc.h(i)\n    qc.ry(-2*math.acos(math.sqrt(m / L)), lis[1])\n    qc.x(lis[1])\n    for i in range(lis[0],lis[1]):\n        qc.ch(lis[1], i)\n    qc.x(lis[1])        \n    for i in range(1,len(lis) - 1):\n        qc.x(lis[i]) \n        qc.cry(-2 * math.acos(math.sqrt(2 ** lis[i] / (L - m))), lis[i], lis[i+1])\n        qc.x(lis[i])\n        qc.x(lis[i+1])\n        for j in range(lis[i],lis[i+1]):\n            qc.ch(lis[i+1],j)\n        qc.x(lis[i+1])\n        m = m + 2 ** (lis[i])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A6C7E9427BE09", "submission_order": 1, "result": "WA", "execution_time": "997 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n \n \ndef Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n \n    return qc\n \n \ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(range(n))\n \n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n \n    qc.x(range(n))\n \n    return qc\n \n \ndef U(m: int, n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    if m == 0:\n        qc.h(range(n))\n        return qc\n \n    u = U(m - 1, n, L)\n \n    qc.compose(u, inplace=True)\n    qc.compose(Rt(n, L), inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(Rs(n), inplace=True)\n    qc.compose(u, inplace=True)\n \n    return qc\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    k = math.floor(math.log2(L))\n    if k == 0:\n        return qc\n \n    m = 3\n    qc.compose(U(m, k, L), inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A6F7FC1BCF914", "submission_order": 1, "result": "AC", "execution_time": "3514 ms", "memory": "105 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    v = []\n    s = 0\n    for j in range(n - 1, -1, -1):\n        if ((L-1) >> j) & 1:\n            s += (1 << j)\n            theta = 2 * math.acos(((1 << j) / ((1 << j) + (L - s))) ** 0.5)\n            if(len(v) == 0):\n                qc.ry(theta, j)\n            else:\n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n                cnh = MCMT('h', (n - 1) - j,1)\n                qc.compose(cnh,qubits = list(range(n - 1, j - 1, -1)),inplace=True)\n                qc.mcp(theta, qc.qregs[0][(j+1):], qc.qregs[0][j])\n                cnh = MCMT('h', (n - 1) - j,1)\n                qc.compose(cnh,qubits = list(range(n - 1, j - 1, -1)),inplace=True)\n                \n                for k in range(len(v)):\n                    if v[k] == 0:\n                        qc.x((n - 1) - k)\n            v.append(1)\n        else:\n            v.append(0)\n            continue\n    for j in range(n - 1):\n        if v[j] == 1:\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n            cnh = MCMT('h',j + 1,1)\n            for k in range((n - 1) - j):\n                qc.compose(cnh,qubits = list(range(n - 1, (n - 1) - (j + 1), -1)) + [k],inplace=True)\n            for k in range(j):\n                if(v[k] == 0):\n                    qc.x((n - 1) - k)\n            qc.x((n - 1) - j)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A728D3F247744", "submission_order": 1, "result": "WA", "execution_time": "1002 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = math.ceil(math.log2(L))\n    for i in range(l):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A7F90BB19DC0A", "submission_order": 1, "result": "RE", "execution_time": "765 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n \n    return qc\n \n \ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(range(n))\n \n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n \n    qc.x(range(n))\n \n    return qc\n \n \ndef U(m: int, n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    if m == 0:\n        qc.h(range(n))\n        return qc\n \n    u = U(m - 1, n, L)\n \n    qc.compose(u, inplace=True)\n    qc.compose(Rt(n, L), inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(Rs(n), inplace=True)\n    qc.compose(u, inplace=True)\n \n    return qc\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    k = math.ceil(math.log2(L))\n    if k == 0:\n        return qc\n \n    m = 3\n    qc.compose(U(m, k, L), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A7F90BB19DC0A", "submission_order": 2, "result": "AC", "execution_time": "2320 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n \n    return qc\n \n \ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(range(n))\n \n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n \n    qc.x(range(n))\n \n    return qc\n \n \ndef U(m: int, n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    if m == 0:\n        qc.h(range(n))\n        return qc\n \n    u = U(m - 1, n, L)\n \n    qc.compose(u, inplace=True)\n    qc.compose(Rt(n, L), inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(Rs(n), inplace=True)\n    qc.compose(u, inplace=True)\n \n    return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     \n    k = math.ceil(math.log2(L))\n    if k == 0:\n        return qc\n \n    m = 3\n    qc.compose(U(m, k, L), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A81B388B9FDB6", "submission_order": 1, "result": "AC", "execution_time": "2777 ms", "memory": "102 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\nfrom qiskit.circuit.library import RYGate\n\ndef nya(l):\n    global qc\n    if len(l) == 1:\n      qc.h(l[0])\n    else:\n      print(l)\n      qc.append(HGate().control(len(l) - 1), l)\n  \n\ndef nyan(p,l):\n    global qc\n    if len(l) == 1:\n      qc.ry(p,l[0])\n    else:\n      qc.append(RYGate(p).control(len(l) - 1), l)\n\ndef solve2(n,L,now,l,msk,msk2):\n  if now == -1:\n    return\n  global qc\n  f = []\n  g = []\n  for i in range(2 ** n):\n    if i & msk2 == msk:\n      if (i & (1 << now)) > 0:\n        g.append(i)\n      else:\n        f.append(i)\n  if max(f) >= L:\n    solve2(n,L,now-1,l,msk,msk2 | (1 << now))\n  else:\n    g = g[0:L - max(f) - 1]\n    p = len(g)/(len(f)+len(g))\n    nyan(math.atan((p/(1-p)) ** 0.5)*2, l + [now])\n    l.append(now)\n    msk |= (1 << now)\n    solve2(n,L,now-1,l,msk,msk2 | (1 << now))\n\n    qc.x(now)\n    for i in range(0,now):\n      nya(l + [i])\n    qc.x(now)\n    l.pop()\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    global qc\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    solve2(n,L,n-1,[],0,0)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A84CC08238E4E", "submission_order": 1, "result": "AC", "execution_time": "2175 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import ZGate,XGate,RYGate\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n\n    # Write your code here:\n    \n    # 左n bitが1になっている物の位相を反転\n    def reverse(qubits,qc,start):\n        if qubits-start>1:\n            qc.append(ZGate().control(qubits - 1 - start), range(start,qubits))\n        else:\n            qc.z(start)\n\n    # ある値をall_1に変更する操作\n    # 左何bit目から操作するか指定\n    def to_calcable(qubits,qc,n,start):\n        for i in range(start,qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    d={}\n    for i in range(1<<n):\n        tmp=\"\"\n        for j in bin(i)[2:].rjust(n,\"0\"):\n            tmp+=j\n            d.setdefault(tmp,0)\n\n    for i in range(L):\n        s=bin(i)[2:].rjust(n,\"0\")\n        tmp=\"\"\n        for i in s:\n            tmp+=i\n            d[tmp]+=1\n\n    # 指定したbit(ゼロ状態)が0になる確率をratioにする\n\n    # 指定したcontroll bitがすべて1の場合にbit(ゼロ状態)が0になる確率をratioにする    \n    def crotate(qc,bits,p0):\n        theta=math.acos(p0*2-1)\n        if len(bits)==1:\n            qc.ry(theta,bits[0])\n        else:\n            qc.append(RYGate(theta).control(len(bits)-1),bits)\n\n    \n    def dfs(prefix,bit,qc,n):\n        # print(\"call\",prefix,bit)\n        prefix0=prefix+\"0\"\n        prefix1=prefix+\"1\"\n        v=int(prefix.ljust(n,\"0\"),2)\n\n\n        if bit==-1 or d.get(prefix0)+d.get(prefix1)==0:return\n        if prefix==\"\":\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            to_calcable(n,qc,v,0)\n            crotate(qc,[bit],p0)\n            to_calcable(n,qc,v,0)\n            dfs(prefix0,bit-1,qc,n)\n            dfs(prefix1,bit-1,qc,n)\n        elif bit>=0:\n            # print(prefix,d[prefix+\"0\"],d[prefix+\"1\"])\n            p0=d[prefix0]/(d[prefix0]+d[prefix1])\n            if p0==0.5:\n                to_calcable(n,qc,v,0)\n                for b in range(bit,-1,-1):\n                    crotate(qc,list(range(n-1,bit,-1))+[b],p0)\n                to_calcable(n,qc,v,0)\n            else:\n                to_calcable(n,qc,v,0)\n                crotate(qc,list(range(n-1,bit-1,-1)),p0)\n                to_calcable(n,qc,v,0)\n                dfs(prefix0,bit-1,qc,n)\n                dfs(prefix1,bit-1,qc,n)\n\n    dfs(\"\",n-1,qc,n)\n    # depth = qc.depth()\n    # print(\"量子回路の深さ:\", depth)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A8C85A9AF543B", "submission_order": 1, "result": "WA", "execution_time": "2198 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \ndef add_rule(qc: QuantumCircuit, n: int, suffix: list[int], Lpre: int) -> None:\n    k = len(suffix)\n    split_idx = n - k - 1\n\n    #print(f\"Lpre={Lpre}, split_idx={split_idx}\")\n    num = 1 << split_idx\n    denom = Lpre\n    #print(f\"{num}/{denom}\")\n    theta = math.acos(math.sqrt(num/denom)) * 2\n    if k > 0:\n        idx = n - 1\n        for bit in suffix:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n        #print(\"ry\", k, range(split_idx + 1, n))\n        qc.append(RYGate(theta).control(k), list(range(split_idx + 1, n)) + [split_idx])\n        idx = n - 1\n        for bit in suffix:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n    else:\n        qc.ry(theta, n - 1)\n\n    #print(suffix)\n    for i in range(0, split_idx):\n        idx = n - 1\n        for bit in suffix + [0]:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n\n        size = k + 1\n        qubits = list(range(split_idx, n)) + [i]\n        #print(size, qubits)\n        qc.append(HGate().control(size), qubits)\n\n        idx = n - 1\n        for bit in suffix + [0]:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if L == (1 << n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n\n    cnt = 0\n    suffix = []\n    Lpre = L\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            add_rule(qc, n, suffix, Lpre)\n            if cnt == 1:\n                break\n            Lpre -= (1 << i)\n            suffix.append(1)\n        else:\n            suffix.append(0)\n        \n        cnt += 1\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A8C85A9AF543B", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \ndef add_rule(qc: QuantumCircuit, n: int, suffix: list[int], Lpre: int) -> None:\n    k = len(suffix)\n    split_idx = n - k - 1\n\n    #print(f\"Lpre={Lpre}, split_idx={split_idx}\")\n    num = 1 << split_idx\n    denom = Lpre\n    #print(f\"{num}/{denom}\")\n    theta = math.acos(math.sqrt(num/denom)) * 2\n    if k > 0:\n        idx = n - 1\n        for bit in suffix:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n        #print(\"ry\", k, range(split_idx + 1, n))\n        qc.append(RYGate(theta).control(k), list(range(split_idx + 1, n)) + [split_idx])\n        idx = n - 1\n        for bit in suffix:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n    else:\n        qc.ry(theta, n - 1)\n\n    #print(suffix)\n    for i in range(0, split_idx):\n        idx = n - 1\n        for bit in suffix + [0]:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n\n        size = k + 1\n        qubits = list(range(split_idx, n)) + [i]\n        #print(size, qubits)\n        qc.append(HGate().control(size), qubits)\n\n        idx = n - 1\n        for bit in suffix + [0]:\n            if bit == 0:\n                qc.x(idx)\n            idx -= 1\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if L == (1 << n):\n        for i in range(n):\n            qc.h(i)\n        return qc\n\n    cnt = 0\n    suffix = []\n    Lpre = L\n    for i in range(n - 1, -1, -1):\n        if L & (1 << i):\n            add_rule(qc, n, suffix, Lpre)\n            Lpre -= (1 << i)\n            suffix.append(1)\n        else:\n            suffix.append(0)\n        \n        cnt += 1\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A99A0AC6B96BB", "submission_order": 1, "result": "AC", "execution_time": "2004 ms", "memory": "94 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\ndef Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n\n    return qc\n\n\ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n\n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n\n    qc.x(range(n))\n\n    return qc\n\n\ndef U(m: int, n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if m == 0:\n        qc.h(range(n))\n        return qc\n\n    u = U(m - 1, n, L)\n\n    qc.compose(u, inplace=True)\n    qc.compose(Rt(n, L), inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(Rs(n), inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    k = math.ceil(math.log2(L))\n    if k == 0:\n        return qc\n\n    m = 3\n    qc.compose(U(m, k, L), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "A9F609B93B0CD", "submission_order": 1, "result": "RE", "execution_time": "1302 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\nfrom math import atan2, sqrt\n\ndef seq(low, hi):\n  return list(range(low, hi))\n\ndef solve(n : int, L : int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  n = int.bit_length(L)\n\n  def bit(i : int) -> bool:\n    return (L & (1 << i)) != 0\n\n  assert bit(n-1)\n  assert 2 ** (n-1) < L <= 2 ** n\n  # Split |0> to a|0> + b|0>\n  #   where |a|^2 : |b|^2 = 2^{n-1} : L - 2^{n-1}\n  # \\cos(t/2) = \\sqrt(2^{n-1}/L)\n  # \\sin(t/2) = \\sqrt((L - 2^{n-1})/L)\n  # e.g for L = 11 = 0b1011, 8 for 0xxx, 3 for 1xxx\n  t = 2 * atan2(sqrt(L-2**(n-1)), sqrt(2**(n-1)))\n  qc.ry(t, n-1)\n\n  # Distribute lower bits for |0> to all 2^{n-1} patterns.\n  qc.x(n-1)\n  for i in range(n-1):\n    qc.ch(n-1, i)\n  qc.x(n-1)\n\n  for i in range(n-2, -1, -1):\n    if not bit(i):\n      qc.x(i)\n      continue\n\n    # e.g. for L = 0b1011 and i = 1, 2 for 100x, 1 for 101x\n    s = L & ((1 << (i+1)) - 1) \n    t = 2 * atan2(sqrt(s-2**(i-1)), sqrt(2**(i-1)))\n    qc.mcry(t, seq(i+1, n), i)\n\n    if i > 0:\n      qc.mcx(seq(i+1, n), i)\n      for j in range(i):\n        qc.append(HGate().control(n-i), seq(i, n) + [j])\n      qc.mcx(seq(i+1, n), i)\n\n  for i in range(n):\n    if not bit(i):\n      qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA0BA1357E843", "submission_order": 1, "result": "UGE", "execution_time": "1162 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 2**n:\n        for j in range(n):\n            qc.h(j)\n    else:\n        flip = []\n        for i in range(n):\n            if L >= 2**(n-1-i):\n                theta = math.acos(math.sqrt(2**(n-1-i)/L)) * 2\n                if i != 0:\n                    qc.mcry(theta, [n-1-_ for _ in range(i)], n-1-i)\n                else:\n                    qc.ry(theta, n-1)\n                qc.x(n-1-i)\n                for j in range(n - 1 - i):\n                    qc.append(HGate().control(i + 1), [n-1-_ for _ in range(i + 1)] + [j])\n                qc.x(n-1-i)\n            else:\n                qc.x(n-1-i)\n                flip.append(n-1-i)\n            L %= 2**(n-1-i)\n        for f in flip:\n            qc.x(f)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA0BA1357E843", "submission_order": 2, "result": "AC", "execution_time": "2589 ms", "memory": "96 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 2**n:\n        for j in range(n):\n            qc.h(j)\n    else:\n        flip = []\n        for i in range(n):\n            if L >= 2**(n-1-i):\n                theta = math.acos(math.sqrt(2**(n-1-i)/L)) * 2\n                if i != 0:\n                    qc.append(RYGate(theta).control(i), [n-1-_ for _ in range(i + 1)])\n                else:\n                    qc.ry(theta, n-1)\n                qc.x(n-1-i)\n                for j in range(n - 1 - i):\n                    qc.append(HGate().control(i + 1), [n-1-_ for _ in range(i + 1)] + [j])\n                qc.x(n-1-i)\n            else:\n                qc.x(n-1-i)\n                flip.append(n-1-i)\n            L %= 2**(n-1-i)\n        for f in flip:\n            qc.x(f)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA4B593940A42", "submission_order": 1, "result": "AC", "execution_time": "4000 ms", "memory": "104 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        cnt_0 = (L >> (i+1)) + 1\n        cnt_1 = L >> (i+1)\n        theta = math.acos(math.sqrt(cnt_0 / (cnt_0 + cnt_1))) * 2\n        if L >> i & 1 ==  1:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                same += str(nxt)\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                same += str(nxt)\n            if i == 0:\n                qc.ry(theta, 0)\n            else:\n                qc.append(RYGate(theta).control(i, ctrl_state=same), range(i+1))\n        else:\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 1:\n                    qc.append(RYGate(theta).control(i-j, ctrl_state=same+'0'), range(j, i+1))\n                same += str(nxt)\n            same = ''\n            for j in range(i-1, -1, -1):\n                nxt = L >> j & 1\n                if nxt == 0:\n                    qc.append(HGate().control(i-j, ctrl_state=same+'1'), range(j, i+1))\n                same += str(nxt)\n            if i == 0:\n                qc.h(0)\n            else:\n                qc.append(HGate().control(i, ctrl_state=same), range(i+1))\n \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA87E192517EC", "submission_order": 1, "result": "RE", "execution_time": "770 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Compute l0, l1, ..., lk\n    l_values = [int(i) for i in np.binary_repr(M)[::-1]]\n    \n    # Apply X gates on qubits at positions l1, l2, ..., lk\n    for l in l_values[1:]:\n        qc.x(l)\n    \n    # Set M0 = 2^l0\n    M0 = 2**l_values[0]\n    \n    # If l0 > 0, apply Hadamard gates on the rightmost l0 qubits\n    if l_values[0] > 0:\n        qc.h(range(l_values[0]))\n        \n        # Apply rotation gate RY(theta0) on qubit ql1\n        theta0 = -2 * np.arccos(np.sqrt(M0/M))\n        qc.ry(theta0, l_values[1])\n        \n        # Apply controlled Hadamard gate on qubits lm, lm + 1, ..., lm+1 − 1 conditioned on qlm+1 being 0\n        for i in range(l_values[0], l_values[1]):\n            qc.ch(i, l_values[1])\n    \n    # Apply controlled RY gates and controlled Hadamard gates for m = 1 to k - 1\n    for m in range(1, len(l_values) - 1):\n        theta_m = -2 * np.arccos(np.sqrt(2*l_values[m]/(M - 2**(m-1))))\n        qc.cry(theta_m, l_values[m], l_values[m+1])\n        \n        for i in range(l_values[m], l_values[m+1]):\n            qc.ch(i, l_values[m+1])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA87E192517EC", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Compute l0, l1, ..., lk\n    l_values = [int(i) for i in np.binary_repr(M)[::-1]]\n    \n    # Apply X gates on qubits at positions l1, l2, ..., lk\n    for l in l_values[1:]:\n        qc.x(l)\n    \n    # Set M0 = 2^l0\n    M0 = 2**l_values[0]\n    \n    # If l0 > 0, apply Hadamard gates on the rightmost l0 qubits\n    if l_values[0] > 0:\n        qc.h(range(l_values[0]))\n        \n        # Apply rotation gate RY(theta0) on qubit ql1\n        theta0 = -2 * np.arccos(np.sqrt(M0/M))\n        qc.ry(theta0, l_values[1])\n        \n        # Apply controlled Hadamard gate on qubits lm, lm + 1, ..., lm+1 − 1 conditioned on qlm+1 being 0\n        for i in range(l_values[0], l_values[1]):\n            qc.ch(i, l_values[1])\n    \n    # Apply controlled RY gates and controlled Hadamard gates for m = 1 to k - 1\n    for m in range(1, len(l_values) - 1):\n        theta_m = -2 * np.arccos(np.sqrt(2*l_values[m]/(M - 2**(m-1))))\n        qc.cry(theta_m, l_values[m], l_values[m+1])\n        \n        for i in range(l_values[m], l_values[m+1]):\n            qc.ch(i, l_values[m+1])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA87E192517EC", "submission_order": 3, "result": "RE", "execution_time": "831 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Compute l0, l1, ..., lk\n    binary_rep = bin(M)[2:][::-1]\n    l_values = [int(bit) for bit in binary_rep]\n    \n    # Apply X gates on qubits at positions l1, l2, ..., lk\n    for l in l_values[1:]:\n        qc.x(l)\n    \n    # Set M0 = 2^l0\n    M0 = 2**l_values[0]\n    \n    # If l0 > 0, apply Hadamard gates on the rightmost l0 qubits\n    if l_values[0] > 0:\n        qc.h(range(l_values[0]))\n        \n        # Apply rotation gate RY(theta0) on qubit ql1\n        theta0 = -2 * qc.circuit.acos(qc.circuit.sqrt(M0/M))\n        qc.ry(theta0, l_values[1])\n        \n        # Apply controlled Hadamard gate on qubits lm, lm + 1, ..., lm+1 − 1 conditioned on qlm+1 being 0\n        for i in range(l_values[0], l_values[1]):\n            qc.ch(i, l_values[1])\n    \n    # Apply controlled RY gates and controlled Hadamard gates for m = 1 to k - 1\n    for m in range(1, len(l_values) - 1):\n        theta_m = -2 * qc.circuit.acos(qc.circuit.sqrt(2*l_values[m]/(M - 2**(m-1))))\n        qc.cry(theta_m, l_values[m], l_values[m+1])\n        \n        for i in range(l_values[m], l_values[m+1]):\n            qc.ch(i, l_values[m+1])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA87E192517EC", "submission_order": 4, "result": "RE", "execution_time": "1091 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Compute l0, l1, ..., lk\n    binary_rep = bin(L)[2:][::-1]\n    l_values = [int(bit) for bit in binary_rep]\n\n    # Apply X gates on qubits at positions l1, l2, ..., lk\n    for l in l_values[1:]:\n        qc.x(l)\n\n    # Set M0 = 2^l0\n    M0 = 2**l_values[0]\n\n    # If l0 > 0, apply Hadamard gates on the rightmost l0 qubits\n    if l_values[0] > 0:\n        qc.h(range(l_values[0]))\n\n        # Apply rotation gate RY(theta0) on qubit ql1\n        theta0 = -2 * qc.circuit.acos(qc.circuit.sqrt(M0/L))\n        qc.ry(theta0, l_values[1])\n\n        # Apply controlled Hadamard gate on qubits lm, lm + 1, ..., lm+1 − 1 conditioned on qlm+1 being 0\n        for i in range(l_values[0], l_values[1]):\n            qc.ch(i, l_values[1])\n\n    # Apply controlled RY gates and controlled Hadamard gates for m = 1 to k - 1\n    for m in range(1, len(l_values) - 1):\n        theta_m = -2 * qc.circuit.acos(qc.circuit.sqrt(2*l_values[m]/(L - 2**(m-1))))\n        qc.cry(theta_m, l_values[m], l_values[m+1])\n\n        for i in range(l_values[m], l_values[m+1]):\n            qc.ch(i, l_values[m+1])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA87E192517EC", "submission_order": 5, "result": "RE", "execution_time": "1181 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # Compute l0, l1, ..., lk\n    binary_rep = bin(L)[2:][::-1]\n    l_values = [int(bit) for bit in binary_rep]\n\n    # Apply X gates on qubits at positions l1, l2, ..., lk\n    for l in l_values[1:]:\n        qc.x(l)\n\n    # Set M0 = 2^l0\n    M0 = 2**l_values[0]\n\n    # If l0 > 0, apply Hadamard gates on the rightmost l0 qubits\n    if l_values[0] > 0:\n        qc.h(range(l_values[0]))\n\n        # Apply rotation gate RY(theta0) on qubit ql1\n        theta0 = -2 * qc.circuit.acos(qc.circuit.sqrt(M0/L))\n        qc.ry(theta0, l_values[1])\n\n        # Apply controlled Hadamard gate on qubits lm, lm + 1, ..., lm+1 − 1 conditioned on qlm+1 being 0\n        for i in range(l_values[0], l_values[1]):\n            qc.ch(i, l_values[1])\n\n    # Apply controlled RY gates and controlled Hadamard gates for m = 1 to k - 1\n    for m in range(1, len(l_values) - 1):\n        theta_m = -2 * qc.circuit.acos(qc.circuit.sqrt(2*l_values[m]/(L - 2**(m-1))))\n        qc.cry(theta_m, l_values[m], l_values[m+1])\n\n        for i in range(l_values[m], l_values[m+1]):\n            qc.ch(i, l_values[m+1])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA954A7DC08AB", "submission_order": 1, "result": "RE", "execution_time": "2485 ms", "memory": "170 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef apply_controlled_ry_all_except_k(qc: QuantumCircuit, th: float, k:int):\n    n = qc.num_qubits\n    control_qubits = [i for i in range(n) if i != k]\n    target_qubit = k\n    controlled_ry = RYGate(th).control(len(control_qubits))\n    qc.append(controlled_ry, control_qubits + [target_qubit])\n\ndef make_qc(qc: QuantumCircuit, L: int, k: int, state: int) -> QuantumCircuit:\n    if(L == 1):\n        return qc\n\n    n = qc.num_qubits\n\n    for i in range(n):\n        if not ((1 >> i) & state):\n            qc.x(i)\n\n    L1 = int((L + 1) / 2)\n    L2 = L - L1\n\n    th = 2 * math.atan(math.sqrt(L2 / L1))\n    apply_controlled_ry_all_except_k(qc, th, k) \n\n    for i in range(n):\n        if not ((1 >> i) & state):\n            qc.x(i)\n\n    make_qc(qc, L1, k + 1, state)\n    make_qc(qc, L2, k + 1, state + 2 ** k)\n\n    return qc\n    \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    make_qc(qc, L, 0, 0)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA954A7DC08AB", "submission_order": 2, "result": "RE", "execution_time": "2313 ms", "memory": "169 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef apply_controlled_ry_all_except_k(qc: QuantumCircuit, th: float, k:int):\n    n = qc.num_qubits\n    control_qubits = [i for i in range(n) if i != k]\n    target_qubit = k\n    controlled_ry = RYGate(th).control(len(control_qubits))\n    qc.append(controlled_ry, control_qubits + [target_qubit])\n\ndef make_qc(qc: QuantumCircuit, L: int, k: int, state: int) -> QuantumCircuit:\n    if(L == 1):\n        return qc\n\n    n = qc.num_qubits\n\n    for i in range(n):\n        if not ((1 << i) & state):\n            qc.x(i)\n\n    L1 = int((L + 1) / 2)\n    L2 = L - L1\n\n    th = 2 * math.atan(math.sqrt(L2 / L1))\n    apply_controlled_ry_all_except_k(qc, th, k) \n\n    for i in range(n):\n        if not ((1 << i) & state):\n            qc.x(i)\n\n    make_qc(qc, L1, k + 1, state)\n    make_qc(qc, L2, k + 1, state + 2 ** k)\n\n    return qc\n    \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    make_qc(qc, L, 0, 0)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA954A7DC08AB", "submission_order": 3, "result": "RE", "execution_time": "2361 ms", "memory": "169 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef apply_controlled_ry_all_except_k(qc: QuantumCircuit, th: float, k:int):\n    n = qc.num_qubits\n    control_qubits = [i for i in range(n) if i != k]\n    target_qubit = k\n    controlled_ry = RYGate(th).control(len(control_qubits))\n    qc.append(controlled_ry, control_qubits + [target_qubit])\n\ndef make_qc(qc: QuantumCircuit, L: int, k: int, state: int) -> QuantumCircuit:\n    if L == 1:\n        return qc\n\n    n = qc.num_qubits\n\n    for i in range(n):\n        if not ((1 << i) & state):\n            qc.x(i)\n\n    L1 = int((L + 1) / 2)\n    L2 = L - L1\n\n    th = 2 * math.atan(math.sqrt(L2 / L1))\n    apply_controlled_ry_all_except_k(qc, th, k) \n\n    for i in range(n):\n        if not ((1 << i) & state):\n            qc.x(i)\n\n    make_qc(qc, L1, k + 1, state)\n    make_qc(qc, L2, k + 1, state + 2 ** k)\n\n    return qc\n    \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    if n != 0:\n        make_qc(qc, L, 0, 0)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA954A7DC08AB", "submission_order": 4, "result": "WA", "execution_time": "2209 ms", "memory": "169 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef apply_controlled_ry_all_except_k(qc: QuantumCircuit, th: float, k:int):\n    n = qc.num_qubits\n    control_qubits = [i for i in range(n) if i != k]\n    target_qubit = k\n    controlled_ry = RYGate(th).control(len(control_qubits))\n    qc.append(controlled_ry, control_qubits + [target_qubit])\n\ndef make_qc(qc: QuantumCircuit, L: int, k: int, state: int) -> QuantumCircuit:\n    if L == 1:\n        return qc\n\n    n = qc.num_qubits\n\n    for i in range(n):\n        if not ((1 << i) & state):\n            qc.x(i)\n\n    L1 = int((L + 1) / 2)\n    L2 = L - L1\n\n    th = 2 * math.atan(math.sqrt(L2 / L1))\n    apply_controlled_ry_all_except_k(qc, th, k) \n\n    for i in range(n):\n        if not ((1 << i) & state):\n            qc.x(i)\n\n    make_qc(qc, L1, k + 1, state)\n    make_qc(qc, L2, k + 1, state + 2 ** k)\n\n    return qc\n    \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    if n > 1:\n        make_qc(qc, L, 0, 0)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AA954A7DC08AB", "submission_order": 5, "result": "DLE", "execution_time": "3000 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef apply_controlled_ry_all_except_k(qc: QuantumCircuit, th: float, k:int):\n    n = qc.num_qubits\n    control_qubits = [i for i in range(n) if i != k]\n    target_qubit = k\n    controlled_ry = RYGate(th).control(len(control_qubits))\n    qc.append(controlled_ry, control_qubits + [target_qubit])\n\ndef make_qc(qc: QuantumCircuit, L: int, k: int, state: int) -> QuantumCircuit:\n    if L == 1:\n        return qc\n\n    n = qc.num_qubits\n\n    for i in range(n):\n        if not ((1 << i) & state):\n            qc.x(i)\n\n    L1 = int((L + 1) / 2)\n    L2 = L - L1\n\n    th = 2 * math.atan(math.sqrt(L2 / L1))\n    apply_controlled_ry_all_except_k(qc, th, k) \n\n    for i in range(n):\n        if not ((1 << i) & state):\n            qc.x(i)\n\n    make_qc(qc, L1, k + 1, state)\n    make_qc(qc, L2, k + 1, state + 2 ** k)\n\n    return qc\n    \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 2:\n            qc.h(0)\n    \n    else:\n        make_qc(qc, L, 0, 0)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB31011F266BF", "submission_order": 1, "result": "WA", "execution_time": "1161 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nfrom math import sqrt, acos, asin\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    def rec(n: int, L: int, control: list[int]):\n        if n == 0:\n            return\n        n -= 1\n        w = 1 << n\n        def RY():\n            if control:\n                qc.ry(theta, n)\n            else:\n                qc.append(RYGate(theta).control(len(control)), control + [n])\n        if L <= w:\n            qc.x(n)\n            rec(n, L, control + [n])\n            qc.x(n)\n            return\n        theta = asin(sqrt(w / L)) * 2\n        def H(i):\n            qc.append(HGate().control(len(control) + 1), control + [n, i])\n        for i in range(n):\n            H(i)\n        qc.x(n)\n        rec(n, L - w, control + [n])\n\n    \n    rec(n, L, [])\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB31011F266BF", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport matplotlib.pyplot as plt\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nfrom math import sqrt, acos, asin\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    def rec(n: int, L: int, control: list[int]):\n        if n == 0:\n            return\n        n -= 1\n        w = 1 << n\n        def RY():\n            if control:\n                qc.append(RYGate(theta).control(len(control)), control + [n])\n            else:\n                qc.ry(theta, n)\n        if L <= w:\n            qc.x(n)\n            rec(n, L, control + [n])\n            qc.x(n)\n            return\n        theta = asin(sqrt(w / L)) * 2\n        RY()\n        def H(i):\n            qc.append(HGate().control(len(control) + 1), control + [n, i])\n        for i in range(n):\n            H(i)\n        qc.x(n)\n        rec(n, L - w, control + [n])\n\n    \n    rec(n, L, [])\n    \n    return qc\n\nqc = solve(1, 2)\nfig = qc.draw(output='mpl')\nplt.show()\n'''"}
{"problem": "QPC001_C2", "user": "AB31011F266BF", "submission_order": 3, "result": "AC", "execution_time": "3383 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate\nfrom math import sqrt, acos, asin\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    def rec(n: int, L: int, control: list[int]):\n        if n == 0:\n            return\n        n -= 1\n        w = 1 << n\n        def RY():\n            if control:\n                qc.append(RYGate(theta).control(len(control)), control + [n])\n            else:\n                qc.ry(theta, n)\n        if L <= w:\n            qc.x(n)\n            rec(n, L, control + [n])\n            qc.x(n)\n            return\n        theta = asin(sqrt(w / L)) * 2\n        RY()\n        def H(i):\n            qc.append(HGate().control(len(control) + 1), control + [n, i])\n        for i in range(n):\n            H(i)\n        qc.x(n)\n        rec(n, L - w, control + [n])\n\n    \n    rec(n, L, [])\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB33DE6DF37CE", "submission_order": 1, "result": "RE", "execution_time": "872 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef uniform_algorithm(M, n):\n    # バイナリ表記の逆順で1の位置を取得\n    binary_str = bin(M)[2:][::-1]\n    print(binary_str)\n    locations_of_1 = [i for i, bit in enumerate(binary_str) if bit == '1']\n    print(locations_of_1)\n    # 量子回路の初期化\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if M == 2:\n            qc.h(0)\n    elif not log2(M).is_integer():\n        # Xゲートを指定の位置に適用\n        for loc in locations_of_1[1:]:\n            qc.append(XGate(), [loc])\n\n        # M0が偶数の場合、右端のl0ビットに対してHadamardゲートを適用\n        M0 = 2 ** locations_of_1[0]\n        if M0 % 2 == 0:\n            for i in range(locations_of_1[0]):\n                qc.append(HGate(), [i])\n\n        # 回転ゲートのパラメータ\n        theta0 = -2 * acos(sqrt(M0 / M))\n    \n        # RYゲートを適用\n        qc.append(RYGate(theta0), [locations_of_1[1]])\n\n        # 制御Hadamardゲートを適用\n        for i in range(locations_of_1[0], locations_of_1[1]):\n            qc.x(locations_of_1[1])\n            qc.append(HGate().control(), [locations_of_1[1], i])\n            qc.x(locations_of_1[1])\n\n        # k回の繰り返し\n        Mm = M0\n        for m in range(1, len(locations_of_1)-1):\n            # 回転ゲートのパラメータ\n            theta_m = -2 * acos(sqrt(2**locations_of_1[m] / (M - Mm)))\n        \n            # 制御RYゲートを適用\n            qc.x(locations_of_1[m])\n            qc.append(RYGate(theta_m).control(), [locations_of_1[m], locations_of_1[m+1]])\n            qc.x(locations_of_1[m])\n            # 制御Hadamardゲートを適用\n            for i in range(locations_of_1[m], locations_of_1[m+1]):\n                qc.x(locations_of_1[m+1])\n                qc.append(HGate().control(), [locations_of_1[m+1],locations_of_1[m]])\n                qc.x(locations_of_1[m+1])\n            Mm += 2**locations_of_1[m]\n    else:\n        qc.h(range(int(log2(M))))\n\n\n\n    return qc\n\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = uniform_algorithm(L,n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB33DE6DF37CE", "submission_order": 2, "result": "RE", "execution_time": "1178 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble\nfrom qiskit.circuit.library import XGate, HGate, U3Gate, RYGate\nfrom math import acos, sqrt, log2\n\ndef uniform_algorithm(M, n):\n    # バイナリ表記の逆順で1の位置を取得\n    binary_str = bin(M)[2:][::-1]\n    print(binary_str)\n    locations_of_1 = [i for i, bit in enumerate(binary_str) if bit == '1']\n    print(locations_of_1)\n    # 量子回路の初期化\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if M == 2:\n            qc.h(0)\n    elif not log2(M).is_integer():\n        # Xゲートを指定の位置に適用\n        for loc in locations_of_1[1:]:\n            qc.append(XGate(), [loc])\n\n        # M0が偶数の場合、右端のl0ビットに対してHadamardゲートを適用\n        M0 = 2 ** locations_of_1[0]\n        if M0 % 2 == 0:\n            for i in range(locations_of_1[0]):\n                qc.append(HGate(), [i])\n\n        # 回転ゲートのパラメータ\n        theta0 = -2 * acos(sqrt(M0 / M))\n    \n        # RYゲートを適用\n        qc.append(RYGate(theta0), [locations_of_1[1]])\n\n        # 制御Hadamardゲートを適用\n        for i in range(locations_of_1[0], locations_of_1[1]):\n            qc.x(locations_of_1[1])\n            qc.append(HGate().control(), [locations_of_1[1], i])\n            qc.x(locations_of_1[1])\n\n        # k回の繰り返し\n        Mm = M0\n        for m in range(1, len(locations_of_1)-1):\n            # 回転ゲートのパラメータ\n            theta_m = -2 * acos(sqrt(2**locations_of_1[m] / (M - Mm)))\n        \n            # 制御RYゲートを適用\n            qc.x(locations_of_1[m])\n            qc.append(RYGate(theta_m).control(), [locations_of_1[m], locations_of_1[m+1]])\n            qc.x(locations_of_1[m])\n            # 制御Hadamardゲートを適用\n            for i in range(locations_of_1[m], locations_of_1[m+1]):\n                qc.x(locations_of_1[m+1])\n                qc.append(HGate().control(), [locations_of_1[m+1],locations_of_1[m]])\n                qc.x(locations_of_1[m+1])\n            Mm += 2**locations_of_1[m]\n    else:\n        qc.h(range(int(log2(M))))\n\n\n\n    return qc\n\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = uniform_algorithm(L,n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB33DE6DF37CE", "submission_order": 3, "result": "RE", "execution_time": "1895 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble\nfrom qiskit.circuit.library import XGate, HGate, U3Gate, RYGate\nfrom math import acos, sqrt, log2\n\ndef uniform_algorithm(M, n):\n    # バイナリ表記の逆順で1の位置を取得\n    binary_str = bin(M)[2:][::-1]\n    print(binary_str)\n    locations_of_1 = [i for i, bit in enumerate(binary_str) if bit == '1']\n    print(locations_of_1)\n    # 量子回路の初期化\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if M == 2:\n            qc.h(0)\n    elif not log2(M).is_integer():\n        # Xゲートを指定の位置に適用\n        for loc in locations_of_1[1:]:\n            qc.append(XGate(), [loc])\n\n        # M0が偶数の場合、右端のl0ビットに対してHadamardゲートを適用\n        M0 = 2 ** locations_of_1[0]\n        if M0 % 2 == 0:\n            for i in range(locations_of_1[0]):\n                qc.append(HGate(), [i])\n\n        # 回転ゲートのパラメータ\n        theta0 = -2 * acos(sqrt(M0 / M))\n    \n        # RYゲートを適用\n        qc.append(RYGate(theta0), [locations_of_1[1]])\n\n        # 制御Hadamardゲートを適用\n        for i in range(locations_of_1[0], locations_of_1[1]):\n            qc.x(locations_of_1[1])\n            qc.append(HGate().control(), [locations_of_1[1], i])\n            qc.x(locations_of_1[1])\n\n        # k回の繰り返し\n        Mm = M0\n        for m in range(1, len(locations_of_1)-1):\n            # 回転ゲートのパラメータ\n            theta_m = -2 * acos(sqrt(2**locations_of_1[m] / (M - Mm)))\n        \n            # 制御RYゲートを適用\n            qc.x(locations_of_1[m])\n            qc.append(RYGate(theta_m).control(), [locations_of_1[m], locations_of_1[m+1]])\n            qc.x(locations_of_1[m])\n            # 制御Hadamardゲートを適用\n            for i in range(locations_of_1[m], locations_of_1[m+1]):\n                qc.x(locations_of_1[m+1])\n                qc.append(HGate().control(), [locations_of_1[m+1],locations_of_1[m]])\n                qc.x(locations_of_1[m+1])\n            Mm += 2**locations_of_1[m]\n    else:\n        qc.h(range(int(log2(M))))\n\n    \n    for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n\n\n\n    return qc\n\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = uniform_algorithm(L,n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB33DE6DF37CE", "submission_order": 4, "result": "RE", "execution_time": "1419 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble\nfrom qiskit.circuit.library import XGate, HGate, U3Gate, RYGate\nfrom math import acos, sqrt, log2\ndef uniform_algorithm(M, n):\n    # バイナリ表記の逆順で1の位置を取得\n    binary_str = bin(M)[2:][::-1]\n    print(binary_str)\n    locations_of_1 = [i for i, bit in enumerate(binary_str) if bit == '1']\n    print(locations_of_1)\n    # 量子回路の初期化\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if M == 2:\n            qc.h(0)\n    elif not log2(M).is_integer():\n        # Xゲートを指定の位置に適用\n        for loc in locations_of_1[1:]:\n            qc.append(XGate(), [loc])\n\n        # M0が偶数の場合、右端のl0ビットに対してHadamardゲートを適用\n        M0 = 2 ** locations_of_1[0]\n        if M0 % 2 == 0:\n            for i in range(locations_of_1[0]):\n                qc.append(HGate(), [i])\n\n        # 回転ゲートのパラメータ\n        theta0 = -2 * acos(sqrt(M0 / M))\n    \n        # RYゲートを適用\n        qc.append(RYGate(theta0), [locations_of_1[1]])\n\n        # 制御Hadamardゲートを適用\n        for i in range(locations_of_1[0], locations_of_1[1]):\n            qc.x(locations_of_1[1])\n            qc.append(HGate().control(), [locations_of_1[1], i])\n            qc.x(locations_of_1[1])\n\n        # k回の繰り返し\n        Mm = M0\n        print(len(locations_of_1))\n        for m in range(1, len(locations_of_1)-1):\n            print(m)\n            # 回転ゲートのパラメータ\n            theta_m = -2 * acos(sqrt(2**locations_of_1[m] / (M - Mm)))\n        \n            # 制御RYゲートを適用\n            qc.x(locations_of_1[m])\n            qc.append(RYGate(theta_m).control(), [locations_of_1[m], locations_of_1[m+1]])\n            qc.x(locations_of_1[m])\n            # 制御Hadamardゲートを適用\n            for i in range(locations_of_1[m], locations_of_1[m+1]):\n                qc.x(locations_of_1[m+1])\n                qc.append(HGate().control(), [locations_of_1[m+1],i])\n                qc.x(locations_of_1[m+1])\n            Mm += 2**locations_of_1[m]\n    else:\n        qc.h(range(int(log2(M))))\n\n\n    return qc\n\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = uniform_algorithm(L,n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB33DE6DF37CE", "submission_order": 5, "result": "RE", "execution_time": "827 ms", "memory": "78 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble\nfrom qiskit.circuit.library import XGate, HGate, U3Gate, RYGate\nfrom math import acos, sqrt, log2\ndef uniform_algorithm(M, n):\n    # バイナリ表記の逆順で1の位置を取得\n    binary_str = bin(M)[2:][::-1]\n    print(binary_str)\n    locations_of_1 = [i for i, bit in enumerate(binary_str) if bit == '1']\n    print(locations_of_1)\n    # 量子回路の初期化\n    qc = QuantumCircuit(n)\n    f n == 1:\n        if M == 2:\n            qc.h(0)\n    elif M == 1:\n        qc.x(0)\n        qc.x(0)\n    elif not log2(M).is_integer():\n        # Xゲートを指定の位置に適用\n        for loc in locations_of_1[1:]:\n            qc.append(XGate(), [loc])\n\n        # M0が偶数の場合、右端のl0ビットに対してHadamardゲートを適用\n        M0 = 2 ** locations_of_1[0]\n        if M0 % 2 == 0:\n            for i in range(locations_of_1[0]):\n                qc.append(HGate(), [i])\n\n        # 回転ゲートのパラメータ\n        theta0 = -2 * acos(sqrt(M0 / M))\n    \n        # RYゲートを適用\n        qc.append(RYGate(theta0), [locations_of_1[1]])\n\n        # 制御Hadamardゲートを適用\n        for i in range(locations_of_1[0], locations_of_1[1]):\n            qc.x(locations_of_1[1])\n            qc.append(HGate().control(), [locations_of_1[1], i])\n            qc.x(locations_of_1[1])\n\n        # k回の繰り返し\n        Mm = M0\n        print(len(locations_of_1))\n        for m in range(1, len(locations_of_1)-1):\n            print(m)\n            # 回転ゲートのパラメータ\n            theta_m = -2 * acos(sqrt(2**locations_of_1[m] / (M - Mm)))\n        \n            # 制御RYゲートを適用\n            qc.x(locations_of_1[m])\n            qc.append(RYGate(theta_m).control(), [locations_of_1[m], locations_of_1[m+1]])\n            qc.x(locations_of_1[m])\n            # 制御Hadamardゲートを適用\n            for i in range(locations_of_1[m], locations_of_1[m+1]):\n                qc.x(locations_of_1[m+1])\n                qc.append(HGate().control(), [locations_of_1[m+1],i])\n                qc.x(locations_of_1[m+1])\n            Mm += 2**locations_of_1[m]\n    else:\n        qc.h(range(int(log2(M))))\n\n\n    return qc\n\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = uniform_algorithm(L,n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB33DE6DF37CE", "submission_order": 6, "result": "AC", "execution_time": "1710 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble\nfrom qiskit.circuit.library import XGate, HGate, U3Gate, RYGate\nfrom math import acos, sqrt, log2\ndef uniform_algorithm(M, n):\n    # バイナリ表記の逆順で1の位置を取得\n    binary_str = bin(M)[2:][::-1]\n    print(binary_str)\n    locations_of_1 = [i for i, bit in enumerate(binary_str) if bit == '1']\n    print(locations_of_1)\n    # 量子回路の初期化\n    qc = QuantumCircuit(n)\n    if n == 1:\n        if M == 2:\n            qc.h(0)\n    elif M == 1:\n        qc.x(0)\n        qc.x(0)\n    elif not log2(M).is_integer():\n        # Xゲートを指定の位置に適用\n        for loc in locations_of_1[1:]:\n            qc.append(XGate(), [loc])\n\n        # M0が偶数の場合、右端のl0ビットに対してHadamardゲートを適用\n        M0 = 2 ** locations_of_1[0]\n        if M0 % 2 == 0:\n            for i in range(locations_of_1[0]):\n                qc.append(HGate(), [i])\n\n        # 回転ゲートのパラメータ\n        theta0 = -2 * acos(sqrt(M0 / M))\n    \n        # RYゲートを適用\n        qc.append(RYGate(theta0), [locations_of_1[1]])\n\n        # 制御Hadamardゲートを適用\n        for i in range(locations_of_1[0], locations_of_1[1]):\n            qc.x(locations_of_1[1])\n            qc.append(HGate().control(), [locations_of_1[1], i])\n            qc.x(locations_of_1[1])\n\n        # k回の繰り返し\n        Mm = M0\n        print(len(locations_of_1))\n        for m in range(1, len(locations_of_1)-1):\n            print(m)\n            # 回転ゲートのパラメータ\n            theta_m = -2 * acos(sqrt(2**locations_of_1[m] / (M - Mm)))\n        \n            # 制御RYゲートを適用\n            qc.x(locations_of_1[m])\n            qc.append(RYGate(theta_m).control(), [locations_of_1[m], locations_of_1[m+1]])\n            qc.x(locations_of_1[m])\n            # 制御Hadamardゲートを適用\n            for i in range(locations_of_1[m], locations_of_1[m+1]):\n                qc.x(locations_of_1[m+1])\n                qc.append(HGate().control(), [locations_of_1[m+1],i])\n                qc.x(locations_of_1[m+1])\n            Mm += 2**locations_of_1[m]\n    else:\n        qc.h(range(int(log2(M))))\n\n\n    return qc\n\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = uniform_algorithm(L,n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AB96879705541", "submission_order": 1, "result": "TLE", "execution_time": "6000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    coeff = 1/math.sqrt(L)\n    qc.initialize([coeff]*L + [0]*(2**n-L))\n    return qc.decompose(reps=5)\n'''"}
{"problem": "QPC001_C2", "user": "AB96879705541", "submission_order": 2, "result": "TLE", "execution_time": "6000 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    coeff = 1/math.sqrt(L)\n    qc.initialize([coeff]*L + [0]*(2**n-L))\n    return qc.decompose(reps=10)\n'''"}
{"problem": "QPC001_C2", "user": "AB96879705541", "submission_order": 3, "result": "TLE", "execution_time": "6000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    coeff = 1/math.sqrt(L)\n    qc.initialize([coeff]*L + [0]*(2**n-L))\n    return qc.decompose(reps=15)\n'''"}
{"problem": "QPC001_C2", "user": "AB96879705541", "submission_order": 4, "result": "TLE", "execution_time": "6000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    coeff = 1/math.sqrt(L)\n    qc.initialize([coeff]*L + [0]*(2**n-L))\n    return qc.decompose(reps=20)\n'''"}
{"problem": "QPC001_C2", "user": "ABB6FAEFC2BAC", "submission_order": 1, "result": "RE", "execution_time": "1050 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    l=L-1\n    k=0\n    while l>0:\n        maxi=0\n        for i in range(n-1-k,-1,-1):\n            if 1<<i > l:\n                continue\n            if 1<<i <=l and 1<<(i+1)>l:\n                maxi=max(maxi,i)\n                print(1<<(i))\n                # if i>0:\n                l2=L-1\n                for k1 in range(n-1,i,-1):\n                    if not (1<<k1)&l2:\n                        qc.x(k1)\n                clist=list(range(n-1,i,-1))+[i]\n                cu3_gate = U3Gate(-math.acos(math.sqrt((1<<i))/math.sqrt(l+1))*2,math.pi,0).control(len(clist)-1)\n                print(clist)\n                qc.append(cu3_gate,clist)\n\n                l2=L-1\n                for k1 in range(n-1,i,-1):\n                    if not (1<<k1)&l2:\n                        qc.x(k1)\n\n                qc.x(i)\n                for j in range(n-1,maxi,-1):\n                    qc.x(j)\n                for j in range(0,i):\n                    clist=list(range(n-1,i-1,-1))+[j]\n\n                    c3h_gate = HGate().control(len(clist)-1)\n                    print(clist)\n                    qc.append(c3h_gate,clist)\n                qc.x(i)\n                for j in range(n-1,maxi,-1):\n                    qc.x(j)\n\n                k+=1\n                l=l-(1<<i) # 最上位ビット削除\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "ABB6FAEFC2BAC", "submission_order": 2, "result": "RE", "execution_time": "1063 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    l=L-1\n    k=0\n    while l>0:\n        maxi=0\n        for i in range(n-1-k,-1,-1):\n            if 1<<i > l:\n                continue\n            if 1<<i <=l and 1<<(i+1)>l:\n                maxi=max(maxi,i)\n                print(1<<(i))\n                # if i>0:\n                l2=L-1\n                for k1 in range(n-1,i,-1):\n                    if not (1<<k1)&l2:\n                        qc.x(k1)\n                clist=list(range(n-1,i,-1))+[i]\n                if len(clist)>1:\n                    cu3_gate = U3Gate(-math.acos(math.sqrt((1<<i))/math.sqrt(l+1))*2,math.pi,0).control(len(clist)-1)\n                    print(clist)\n                    qc.append(cu3_gate,clist)\n                else:\n                    qc.u(-math.acos(math.sqrt((1<<i))/math.sqrt(l+1))*2,math.pi,0,i)\n\n                l2=L-1\n                for k1 in range(n-1,i,-1):\n                    if not (1<<k1)&l2:\n                        qc.x(k1)\n\n                qc.x(i)\n                for j in range(n-1,maxi,-1):\n                    qc.x(j)\n                for j in range(0,i):\n                    clist=list(range(n-1,i-1,-1))+[j]\n\n                    c3h_gate = HGate().control(len(clist)-1)\n                    print(clist)\n                    qc.append(c3h_gate,clist)\n                qc.x(i)\n                for j in range(n-1,maxi,-1):\n                    qc.x(j)\n\n                k+=1\n                l=l-(1<<i) # 最上位ビット削除\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "ABEB3CA7A6027", "submission_order": 1, "result": "UGE", "execution_time": "1256 ms", "memory": "82 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef c1(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    while True:\n        print(n)\n        if L > 2 ** (n - 1):\n            qc.h(range(n))\n            return qc\n        n -= 1\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(500):\n        c = c1(n, L)\n        qc.append(c, range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "ABEB3CA7A6027", "submission_order": 2, "result": "UGE", "execution_time": "933 ms", "memory": "83 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef c1(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    while True:\n        print(n)\n        if L > 2 ** (n - 1):\n            qc.h(range(n))\n            return qc\n        n -= 1\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    c = c1(n, L)\n\n    for _ in range(500):\n        qc.append(c, range(n))\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "ABEB3CA7A6027", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit import Aer, transpile, execute\n\n\ndef c1(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    while True:\n        print(n)\n        if L > 2 ** (n - 1):\n            qc.h(range(n))\n            return qc\n        n -= 1\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    c = c1(n, L)\n\n    for _ in range(500):\n        qc &= c\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "ABEB3CA7A6027", "submission_order": 4, "result": "WA", "execution_time": "1225 ms", "memory": "100 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef c1(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if L == 1:\n        return qc\n\n    while True:\n        print(n)\n        if L > 2 ** (n - 1):\n            qc.h(range(n))\n            return qc\n        n -= 1\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    c = c1(n, L)\n\n    for _ in range(500):\n        qc &= c\n\n    return qc\n\n\nsolve(10, 100)\n'''"}
{"problem": "QPC001_C2", "user": "ABEB3CA7A6027", "submission_order": 5, "result": "AC", "execution_time": "1342 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate\nimport math\n\n\ndef Rt(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            continue\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.p(math.pi / 3, i)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - i - 1), range(i, n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n\n    return qc\n\n\ndef Rs(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n\n    if n == 1:\n        qc.p(math.pi / 3, 0)\n    else:\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n\n    qc.x(range(n))\n\n    return qc\n\n\ndef U(m: int, n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if m == 0:\n        qc.h(range(n))\n        return qc\n\n    u = U(m - 1, n, L)\n\n    qc.compose(u, inplace=True)\n    qc.compose(Rt(n, L), inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(Rs(n), inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    if L == 1:\n        return qc\n\n    k = math.ceil(math.log2(L))\n    qc.compose(U(3, k, L), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "ABF3A98409189", "submission_order": 1, "result": "RE", "execution_time": "2308 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef less_than_oracle(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (L & (1 << i)) == 0:\n            qc.x(i)\n    for i in range(n):\n        if (L & (1 << i)) != 0:\n            qc.x(i)\n            if i + 1 < n:\n                qc.append(ZGate().control(n - i - 1), range(i, n))\n            else:\n                qc.z(i)\n            qc.x(i)\n    for i in range(n):\n        if (L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\ndef make_three_uniform() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ry(math.asin(1 / 3), 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    assert L < 2 ** n\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    if L == (2 ** n) // 2:\n        qc.h(n-1)\n        return qc\n    if L == (2 ** n) // 4 * 3:\n        qc.h(n-1)\n        qc.h(n-2)\n        qc.append(make_three_uniform().to_gate(), [n - 2, n - 1])\n        return qc\n\n    theta = math.asin((L / (2 ** n)) ** 0.5)\n    # print(f\"{theta = }\")\n    less = less_than_oracle(n, L)\n    diff = diffusion_oracle(n)\n    for i in range(400):\n        if math.sin((2 * i + 1) * theta) ** 2 > 0.9999:\n            # print(f'break! {i = }')\n            break\n        qc.append(less.to_gate(), range(n))\n        qc.append(diff.to_gate(), range(n))\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     import random\n\n#     n = random.randint(2, 10)\n#     L = random.randint(1, 2 ** n - 1)\n#     # n = 2\n#     # L = 2**(n-2)*3\n#     # theta = L/N, and only broken when n/(4 theta) is a half integer\n#     print(f\"{n = } {L = }\")\n#     qc = solve(n, L)\n#     sv = Statevector(qc)\n#     # print(sv)\n#     prob = (np.abs(sv) ** 2)\n#     print(sum(prob[i] for i in range(L)))\n#     print(f\"{qc.depth() = }\")\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC001_C2", "user": "ABF3A98409189", "submission_order": 2, "result": "UGE", "execution_time": "1685 ms", "memory": "158 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef less_than_oracle(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (L & (1 << i)) == 0:\n            qc.x(i)\n    for i in range(n):\n        if (L & (1 << i)) != 0:\n            qc.x(i)\n            if i + 1 < n:\n                qc.append(ZGate().control(n - i - 1), range(i, n))\n            else:\n                qc.z(i)\n            qc.x(i)\n    for i in range(n):\n        if (L & (1 << i)) == 0:\n            qc.x(i)\n    return qc\n\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\ndef make_three_uniform() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ry(math.asin(1 / 3), 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    assert L <= 2 ** n\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    if L == (2 ** n):\n        return qc\n    if L == (2 ** n) // 2:\n        qc.h(n-1)\n        return qc\n    if L == (2 ** n) // 4 * 3:\n        qc.h(n-1)\n        qc.h(n-2)\n        qc.append(make_three_uniform().to_gate(), [n - 2, n - 1])\n        return qc\n\n    theta = math.asin((L / (2 ** n)) ** 0.5)\n    # print(f\"{theta = }\")\n    less = less_than_oracle(n, L)\n    diff = diffusion_oracle(n)\n    for i in range(400):\n        if math.sin((2 * i + 1) * theta) ** 2 > 0.9999:\n            # print(f'break! {i = }')\n            break\n        qc.append(less.to_gate(), range(n))\n        qc.append(diff.to_gate(), range(n))\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     import random\n\n#     n = random.randint(2, 10)\n#     L = random.randint(1, 2 ** n - 1)\n#     # n = 2\n#     # L = 2**(n-2)*3\n#     # theta = L/N, and only broken when n/(4 theta) is a half integer\n#     print(f\"{n = } {L = }\")\n#     qc = solve(n, L)\n#     sv = Statevector(qc)\n#     # print(sv)\n#     prob = (np.abs(sv) ** 2)\n#     print(sum(prob[i] for i in range(L)))\n#     print(f\"{qc.depth() = }\")\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC001_C2", "user": "AC13A274AD134", "submission_order": 1, "result": "WA", "execution_time": "1032 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for k in range(1, n):\n        if L <= 2**(n-k):\n            qc.x(n-k)\n            qc.h(n-k)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 1, "result": "RE", "execution_time": "907 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    if L == (1<<n):\n        qc = QuantumCircuit(n)\n        return qc\n    else:\n        numbin = bin(L + (1<<n))[3:]\n        qc = QuantumCircuit(n)\n        numbin = numbin.rstrip(\"0\")\n        print(numbin)\n        if numbin[0]== \"1\":\n            qc.x(n-1)\n            qc.z(n-1)\n            qc.x(n-1)\n        else:\n            qc.x(n-1)\n        for pos, v in enumerate(numbin[1:]):\n            pos += 1\n            if v==\"0\":\n                qc.x(n-1-pos)\n            else:\n                qc.x(n-1-pos)\n                nn = pos + 1\n                circuit=QuantumCircuit(nn)\n                circuit.h(nn-1)\n                gate = MCXGate(nn-1)\n                circuit.append(gate, range(nn))\n                circuit.h(nn-1)\n                qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n                qc.x(n-pos-1)\n        for pos, v in enumerate(numbin):\n            if v == \"0\":\n                qc.x(n-pos-1)\n        qc = qc.decompose()\n        return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 2, "result": "RE", "execution_time": "1216 ms", "memory": "80 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCXGate, GroverOperator\nimport math\n\ndef get_oracle(n,L):\n    if L == (1<<n):\n        qc = QuantumCircuit(n)\n        return qc\n    numbin = bin(L + (1<<n))[3:]\n    qc = QuantumCircuit(n)\n    numbin = numbin.rstrip(\"0\")\n    print(numbin)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n\ndef mirror(oracle: QuantumCircuit, n_qubits: int, barrier: bool = False) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    qc.append(oracle.inverse(), list(range(n_qubits)))\n    qc.x(list(range(n_qubits)))\n    qc.h(n_qubits-1)\n    qc.mcx(list(range(n_qubits-1)), n_qubits-1)\n    qc.h(n_qubits-1)\n    qc.x(list(range(n_qubits)))\n    qc.append(oracle, list(range(n_qubits)))\n    qc.global_phase = math.pi\n    return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    oracle = get_oracle(n, L)\n    horacle = QuantumCircuit(n)\n    for i in range(n):\n        horacle.h(i)\n    for i in range(10):\n        gop = GroverOperator(oracle)\n        qc.append(gop, list(range(n)))\n        mirror(horacle, n)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 3, "result": "WA", "execution_time": "1168 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCXGate, GroverOperator\nimport math\n\ndef get_oracle(n,L):\n    if L == (1<<n):\n        qc = QuantumCircuit(n)\n        return qc\n    numbin = bin(L + (1<<n))[3:]\n    qc = QuantumCircuit(n)\n    numbin = numbin.rstrip(\"0\")\n    print(numbin)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n\ndef mirror(oracle: QuantumCircuit, n_qubits: int, barrier: bool = False) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    qc.append(oracle.inverse(), list(range(n_qubits)))\n    qc.x(list(range(n_qubits)))\n    qc.h(n_qubits-1)\n    qc.mcx(list(range(n_qubits-1)), n_qubits-1)\n    qc.h(n_qubits-1)\n    qc.x(list(range(n_qubits)))\n    qc.append(oracle, list(range(n_qubits)))\n    qc.global_phase = math.pi\n    return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    oracle = get_oracle(n, L)\n    horacle = QuantumCircuit(n)\n    for i in range(n):\n        horacle.h(i)\n    for i in range(10):\n        gop = GroverOperator(oracle)\n        qc.append(gop, list(range(n)))\n        \n    qc = qc.decompose().decompose()\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 4, "result": "WA", "execution_time": "1132 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, MCXGate, GroverOperator\nimport math\n\ndef get_oracle(n,L):\n    if L == (1<<n):\n        qc = QuantumCircuit(n)\n        return qc\n    numbin = bin(L + (1<<n))[3:]\n    qc = QuantumCircuit(n)\n    numbin = numbin.rstrip(\"0\")\n    print(numbin)\n    if numbin[0]== \"1\":\n        qc.x(n-1)\n        qc.z(n-1)\n        qc.x(n-1)\n    else:\n        qc.x(n-1)\n    for pos, v in enumerate(numbin[1:]):\n        pos += 1\n        if v==\"0\":\n            qc.x(n-1-pos)\n        else:\n            qc.x(n-1-pos)\n            nn = pos + 1\n            circuit=QuantumCircuit(nn)\n            circuit.h(nn-1)\n            gate = MCXGate(nn-1)\n            circuit.append(gate, range(nn))\n            circuit.h(nn-1)\n            qc.append(circuit.to_gate(), range(n-1,n-2-pos,-1))\n            qc.x(n-pos-1)\n    for pos, v in enumerate(numbin):\n        if v == \"0\":\n            qc.x(n-pos-1)\n    qc = qc.decompose()\n    return qc\n\ndef mirror(oracle: QuantumCircuit, n_qubits: int, barrier: bool = False) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    qc.append(oracle.inverse(), list(range(n_qubits)))\n    qc.x(list(range(n_qubits)))\n    qc.h(n_qubits-1)\n    qc.mcx(list(range(n_qubits-1)), n_qubits-1)\n    qc.h(n_qubits-1)\n    qc.x(list(range(n_qubits)))\n    qc.append(oracle, list(range(n_qubits)))\n    qc.global_phase = math.pi\n    return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    oracle = get_oracle(n, L)\n    #horacle = QuantumCircuit(n)\n    #for i in range(n):\n    #    horacle.h(i)\n    for i in range(2*(1<<(n//2))):\n        gop = GroverOperator(oracle)\n        qc.append(gop, list(range(n)))\n        \n    qc = qc.decompose().decompose()\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 5, "result": "RE", "execution_time": "815 ms", "memory": "79 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate, XGate\nimport math\n\ndef dist(L, n):\n    if L == 1:\n        return [1.0]\n    ret = []\n    for i in range(n):\n        if L < (1<<(i+1)):\n            ret.append(max(L - (1<<i),0))\n            break\n        else:\n            if i==0:\n                ret.append(2)\n            else:\n                ret.append(1<<i)\n    \n    return [r/L for r in ret if r>0]\n\ndef w_state(n_qubits: int, L, control, ctrl_state) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    seq = dist(L, n_qubits)\n    #print(seq)\n    RY = RYGate(-math.asin(seq[0]**0.5)*2)\n    #qc.append(RY, [0])\n    if len(control)>0:\n        RY = RY.control(len(control),ctrl_state=ctrl_state)\n    qc.append(RY, control + [0])\n\n    for i in range(1, len(seq)):\n        RY = RYGate(-math.asin((seq[i]/sum(seq[i:]))**0.5)*2)\n        RY = RY.control(len(control)+i,ctrl_state= \"0\"*i + ctrl_state)\n        qc.append(RY, control + [j for j in range(i)] + [i])\n\n    return qc\n\n\ndef solve() -> QuantumCircuit:\n    n = 4\n    L = 6\n    # qc = QuantumCircuit(4)\n    # qc.h(0)\n    # xg = XGate()\n    # xg = xg.control(2,ctrl_state=\"01\")\n    # qc.append(xg, [0,1,2])\n    # return qc\n    dis = dist(L, n)\n    binlist = []\n    for i in range(len(dis)):\n        if ((1<<i) & L) > 0:\n            binlist.append(1)\n        else:\n            binlist.append(0)\n    qc = QuantumCircuit(n)\n    #return w_state(n,L,[], \"\")\n    b = 1<<(len(binlist)-1)\n    l = L\n    for i in range(len(binlist)):\n        if binlist[-i-1] == 1:\n            if i>0:\n                ctrls = list(range(len(binlist)))[-i:]\n            else:\n                ctrls = []\n            st = bin(L)[2:2+i]\n            #print(ctrls,st,l)\n            _qc = w_state(n, l, ctrls, st)\n            l -= b\n            qc.append(_qc, range(n))\n            for j in range(len(binlist)-i-1):\n                new_st = st + \"\".join([\"1\" if j==k else \"0\" for k in range(1,len(binlist)-i)][::-1])\n                newctrl = [k for k in range(len(binlist) - len(new_st), len(binlist))]\n                #print(\"newst\", new_st, newctrl, j)\n                if j==0:\n                    xg = XGate()\n                    xg = xg.control(len(newctrl), ctrl_state=new_st)\n                    qc.append(xg, newctrl + [0])\n                    hg = HGate()\n                    hg = hg.control(len(newctrl), ctrl_state=new_st)\n                    qc.append(hg, newctrl + [0])\n                else:\n                    for k in range(j):\n                        hg = HGate()\n                        hg = hg.control(len(newctrl), ctrl_state=new_st)\n                        qc.append(hg, newctrl + [k])\n            #break\n        b //= 2\n    qc = qc.decompose().decompose()\n        #    for k in range(j):\n        #         print(j,k)\n        #         hg = HGate()\n        #         hg = hg.control(len(ctrls)+1, ctrl_state=st+\"1\")\n        #         qc.append(hg, ctrls + [j] + [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 6, "result": "RE", "execution_time": "1175 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate, XGate\nimport math\n\ndef dist(L, n):\n    if L == 1:\n        return [1.0]\n    ret = []\n    for i in range(n):\n        if L < (1<<(i+1)):\n            ret.append(max(L - (1<<i),0))\n            break\n        else:\n            if i==0:\n                ret.append(2)\n            else:\n                ret.append(1<<i)\n    \n    return [r/L for r in ret if r>0]\n\ndef w_state(n_qubits: int, L, control, ctrl_state) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    seq = dist(L, n_qubits)\n    #print(seq)\n    RY = RYGate(-math.asin(seq[0]**0.5)*2)\n    #qc.append(RY, [0])\n    if len(control)>0:\n        RY = RY.control(len(control),ctrl_state=ctrl_state)\n    qc.append(RY, control + [0])\n\n    for i in range(1, len(seq)):\n        RY = RYGate(-math.asin((seq[i]/sum(seq[i:]))**0.5)*2)\n        RY = RY.control(len(control)+i,ctrl_state= \"0\"*i + ctrl_state)\n        qc.append(RY, control + [j for j in range(i)] + [i])\n\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    # qc = QuantumCircuit(4)\n    # qc.h(0)\n    # xg = XGate()\n    # xg = xg.control(2,ctrl_state=\"01\")\n    # qc.append(xg, [0,1,2])\n    # return qc\n    dis = dist(L, n)\n    binlist = []\n    for i in range(len(dis)):\n        if ((1<<i) & L) > 0:\n            binlist.append(1)\n        else:\n            binlist.append(0)\n    qc = QuantumCircuit(n)\n    #return w_state(n,L,[], \"\")\n    b = 1<<(len(binlist)-1)\n    l = L\n    for i in range(len(binlist)):\n        if binlist[-i-1] == 1:\n            if i>0:\n                ctrls = list(range(len(binlist)))[-i:]\n            else:\n                ctrls = []\n            st = bin(L)[2:2+i]\n            #print(ctrls,st,l)\n            _qc = w_state(n, l, ctrls, st)\n            l -= b\n            qc.append(_qc, range(n))\n            for j in range(len(binlist)-i-1):\n                new_st = st + \"\".join([\"1\" if j==k else \"0\" for k in range(1,len(binlist)-i)][::-1])\n                newctrl = [k for k in range(len(binlist) - len(new_st), len(binlist))]\n                #print(\"newst\", new_st, newctrl, j)\n                if j==0:\n                    xg = XGate()\n                    xg = xg.control(len(newctrl), ctrl_state=new_st)\n                    qc.append(xg, newctrl + [0])\n                    hg = HGate()\n                    hg = hg.control(len(newctrl), ctrl_state=new_st)\n                    qc.append(hg, newctrl + [0])\n                else:\n                    for k in range(j):\n                        hg = HGate()\n                        hg = hg.control(len(newctrl), ctrl_state=new_st)\n                        qc.append(hg, newctrl + [k])\n            #break\n        b //= 2\n    qc = qc.decompose().decompose()\n        #    for k in range(j):\n        #         print(j,k)\n        #         hg = HGate()\n        #         hg = hg.control(len(ctrls)+1, ctrl_state=st+\"1\")\n        #         qc.append(hg, ctrls + [j] + [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 7, "result": "DLE", "execution_time": "1996 ms", "memory": "93 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate, XGate\nimport math\n\ndef dist(L, n):\n    if L == 1:\n        return [1.0]\n    ret = []\n    for i in range(n):\n        if L < (1<<(i+1)):\n            ret.append(max(L - (1<<i),0))\n            break\n        else:\n            if i==0:\n                ret.append(2)\n            else:\n                ret.append(1<<i)\n    \n    return [r/L for r in ret if r>0]\n\ndef w_state(n_qubits: int, L, control, ctrl_state) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    seq = dist(L, n_qubits)\n    #print(seq)\n    RY = RYGate(-math.asin(seq[0]**0.5)*2)\n    #qc.append(RY, [0])\n    if len(control)>0:\n        RY = RY.control(len(control),ctrl_state=ctrl_state)\n    qc.append(RY, control + [0])\n\n    for i in range(1, len(seq)):\n        RY = RYGate(-math.asin((seq[i]/sum(seq[i:]))**0.5)*2)\n        RY = RY.control(len(control)+i,ctrl_state= \"0\"*i + ctrl_state)\n        qc.append(RY, control + [j for j in range(i)] + [i])\n\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    if L == 1:\n        return QuantumCircuit(n)\n    elif L==2:\n        qc = QuantumCircuit(n)\n        qc.h(0)\n        return qc\n    for i in range(2,n+1):\n        if L==(1<<i):\n            qc = QuantumCircuit(n)\n            for j in range(i):\n                qc.h(j)\n            return qc\n        \n    # qc = QuantumCircuit(4)\n    # qc.h(0)\n    # xg = XGate()\n    # xg = xg.control(2,ctrl_state=\"01\")\n    # qc.append(xg, [0,1,2])\n    # return qc\n    L += 1\n    dis = dist(L, n)\n    binlist = []\n    for i in range(len(dis)):\n        if ((1<<i) & (L-1)) > 0:\n            binlist.append(1)\n        else:\n            binlist.append(0)\n    #print(binlist)\n\n    qc = QuantumCircuit(n)\n    #return w_state(n,L,[], \"\")\n    b = 1<<(len(binlist)-1)\n    L = L -1\n    l = L\n    for i in range(len(binlist)):\n        if binlist[-i-1] == 1:\n            if i>0:\n                ctrls = list(range(len(binlist)))[-i:]\n            else:\n                ctrls = []\n            st = bin(L)[2:2+i]\n            #print(ctrls,st,l)\n            _qc = w_state(n, l, ctrls, st)\n            l -= b\n            qc.append(_qc, range(n))\n            for j in range(len(binlist)-i-1):\n                new_st = st + \"\".join([\"1\" if j==k else \"0\" for k in range(1,len(binlist)-i)][::-1])\n                newctrl = [k for k in range(len(binlist) - len(new_st), len(binlist))]\n                if j>1:\n                    new_st = new_st[:-j+1]\n                    newctrl = newctrl[j-1:]\n                #print(\"newst\", new_st, newctrl, j)\n                if j==0:\n                    xg = XGate()\n                    xg = xg.control(len(newctrl), ctrl_state=new_st)\n                    qc.append(xg, newctrl + [0])\n                    hg = HGate()\n                    hg = hg.control(len(newctrl), ctrl_state=new_st)\n                    qc.append(hg, newctrl + [0])\n                else:\n                    for k in range(j):\n                        hg = HGate()\n                        hg = hg.control(len(newctrl), ctrl_state=new_st)\n                        qc.append(hg, newctrl + [k])\n            #break\n        b //= 2\n    xg = XGate()\n    xg = xg.control(n-1, ctrl_state=bin(L + (1<<n))[3:-1])\n    qc.append(xg, list(range(1,n)) + [0])\n    qc = qc.decompose().decompose()\n        #    for k in range(j):\n        #         print(j,k)\n        #         hg = HGate()\n        #         hg = hg.control(len(ctrls)+1, ctrl_state=st+\"1\")\n        #         qc.append(hg, ctrls + [j] + [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 8, "result": "TLE", "execution_time": "4000 ms", "memory": "102 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate, XGate\nimport math\n\ndef dist(L, n):\n    if L == 1:\n        return [1.0]\n    ret = []\n    for i in range(n):\n        if L < (1<<(i+1)):\n            ret.append(max(L - (1<<i),0))\n            break\n        else:\n            if i==0:\n                ret.append(2)\n            else:\n                ret.append(1<<i)\n    \n    return [r/L for r in ret if r>0]\n\ndef w_state(n_qubits: int, L, control, ctrl_state) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    seq = dist(L, n_qubits)\n    #print(seq)\n    RY = RYGate(-math.asin(seq[0]**0.5)*2)\n    #qc.append(RY, [0])\n    if len(control)>0:\n        RY = RY.control(len(control),ctrl_state=ctrl_state)\n    qc.append(RY, control + [0])\n\n    for i in range(1, len(seq)):\n        RY = RYGate(-math.asin((seq[i]/sum(seq[i:]))**0.5)*2)\n        RY = RY.control(len(control)+i,ctrl_state= \"0\"*i + ctrl_state)\n        qc.append(RY, control + [j for j in range(i)] + [i])\n\n    return qc\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    if L == 1:\n        return QuantumCircuit(n)\n    elif L==2:\n        qc = QuantumCircuit(n)\n        qc.h(0)\n        return qc\n    for i in range(2,n+1):\n        if L==(1<<i):\n            qc = QuantumCircuit(n)\n            for j in range(i):\n                qc.h(j)\n            return qc\n        \n    # qc = QuantumCircuit(4)\n    # qc.h(0)\n    # xg = XGate()\n    # xg = xg.control(2,ctrl_state=\"01\")\n    # qc.append(xg, [0,1,2])\n    # return qc\n    L += 1\n    dis = dist(L, n)\n    binlist = []\n    for i in range(len(dis)):\n        if ((1<<i) & (L-1)) > 0:\n            binlist.append(1)\n        else:\n            binlist.append(0)\n    #print(binlist)\n\n    qc = QuantumCircuit(n)\n    #return w_state(n,L,[], \"\")\n    b = 1<<(len(binlist)-1)\n    L = L -1\n    l = L\n    for i in range(len(binlist)):\n        if binlist[-i-1] == 1:\n            if i>0:\n                ctrls = list(range(len(binlist)))[-i:]\n            else:\n                ctrls = []\n            st = bin(L)[2:2+i]\n            #print(ctrls,st,l)\n            _qc = w_state(n, l, ctrls, st)\n            l -= b\n            qc.append(_qc, range(n))\n            for j in range(len(binlist)-i-1):\n                new_st = st + \"\".join([\"1\" if j==k else \"0\" for k in range(1,len(binlist)-i)][::-1])\n                newctrl = [k for k in range(len(binlist) - len(new_st), len(binlist))]\n                if j>1:\n                    new_st = new_st[:-j+1]\n                    newctrl = newctrl[j-1:]\n                #print(\"newst\", new_st, newctrl, j)\n                if j==0:\n                    xg = XGate()\n                    xg = xg.control(len(newctrl), ctrl_state=new_st)\n                    qc.append(xg, newctrl + [0])\n                    hg = HGate()\n                    hg = hg.control(len(newctrl), ctrl_state=new_st)\n                    qc.append(hg, newctrl + [0])\n                else:\n                    for k in range(j):\n                        hg = HGate()\n                        hg = hg.control(len(newctrl), ctrl_state=new_st)\n                        qc.append(hg, newctrl + [k])\n            #break\n        b //= 2\n    xg = XGate()\n    xg = xg.control(n-1, ctrl_state=bin(L + (1<<n))[3:-1])\n    qc.append(xg, list(range(1,n)) + [0])\n    qc = qc.decompose()\n        #    for k in range(j):\n        #         print(j,k)\n        #         hg = HGate()\n        #         hg = hg.control(len(ctrls)+1, ctrl_state=st+\"1\")\n        #         qc.append(hg, ctrls + [j] + [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD27568DCFEF4", "submission_order": 9, "result": "WA", "execution_time": "1804 ms", "memory": "95 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate, HGate, XGate\nimport math\n\ndef dist(L, n):\n    if L <= 2:\n        return [1.0]\n    ret = []\n    for i in range(n):\n        if L < (1<<(i+1)):\n            ret.append(max(L - (1<<i),0))\n            break\n        else:\n            if i==0:\n                ret.append(2)\n            else:\n                ret.append(1<<i)\n    \n    return [r/L for r in ret if r>0]\n\ndef w_state(n_qubits: int, L, control, ctrl_state) -> QuantumCircuit:\n    qc = QuantumCircuit(n_qubits)\n    seq = dist(L, n_qubits)\n    \n    #print(seq)\n    RY = RYGate(-math.asin((seq[-1])**0.5)*2)\n    #qc.append(RY, [0])\n    if len(control)>0:\n        RY = RY.control(len(control),ctrl_state=ctrl_state)\n    qc.append(RY, control + [len(seq)-1])\n\n    return qc\n\n\ndef solve(n:int, L:int) -> QuantumCircuit:\n    \n    if L == 1:\n        return QuantumCircuit(n)\n    elif L==2:\n        qc = QuantumCircuit(n)\n        qc.h(0)\n        return qc\n    for i in range(2,n+1):\n        if L==(1<<i):\n            qc = QuantumCircuit(n)\n            for j in range(i):\n                qc.h(j)\n            return qc\n        \n    # qc = QuantumCircuit(4)\n    # qc.h(0)\n    # xg = XGate()\n    # xg = xg.control(2,ctrl_state=\"01\")\n    # qc.append(xg, [0,1,2])\n    # return qc\n    L += 1\n    dis = dist(L, n)\n    binlist = []\n    for i in range(len(dis)):\n        if ((1<<i) & (L-1)) > 0:\n            binlist.append(1)\n        else:\n            binlist.append(0)\n    #print(binlist)\n\n    qc = QuantumCircuit(n)\n    #return w_state(n,L,[], \"\")\n    b = 1<<(len(binlist)-1)\n    L = L -1\n    l = L\n    for i in range(len(binlist)):\n        if binlist[-i-1] == 1:\n            if i>0:\n                ctrls = list(range(len(binlist)))[-i:]\n            else:\n                ctrls = []\n            st = bin(L)[2:2+i]\n            #print(ctrls,st,l)\n            _qc = w_state(n, l, ctrls, st)\n            l -= b\n            qc.append(_qc, range(n))\n            new_st = st + \"0\"\n            newctrl = [k for k in range(len(binlist) - len(new_st), len(binlist))]\n            for j in range(len(binlist)-i-1):\n                hg = HGate()\n                hg = hg.control(len(newctrl), ctrl_state=new_st)\n                qc.append(hg, newctrl + [j])\n            #break\n        b //= 2\n    xg = XGate()\n    xg = xg.control(n-1, ctrl_state=bin(L + (1<<n))[3:-1])\n    qc.append(xg, list(range(1,n)) + [0])\n    qc = qc.decompose()\n        #    for k in range(j):\n        #         print(j,k)\n        #         hg = HGate()\n        #         hg = hg.control(len(ctrls)+1, ctrl_state=st+\"1\")\n        #         qc.append(hg, ctrls + [j] + [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport qiskit.circuit.library as qis\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    bits = []\n    ones = []\n    for i in range(n-1, -1, -1):\n        if L & (1<<i) != 0:\n            bits += [(i, ones.copy(), 1)]\n            ones += [i]\n        else:\n            bits += [(i, ones.copy(), 0)]\n\n    for target, controls, bit in bits:\n        for lsb_ctrl_i in range(len(controls), 0, -1):\n\n            ctrl_subset = controls[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate,  ctrl_subset + [target])\n\n        if bit == 1:\n            left = 1<<target\n            right = (L % left) + 1\n\n            wanted_cos = (left/(left + right))**0.5\n            theta = math.acos(wanted_cos)*2\n\n            gate = qis.RXGate(theta=theta)\n            if len(controls) != 0:\n                gate = gate.control(num_ctrl_qubits=len(controls))\n            qc.append(gate, controls + [target])\n            \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 2, "result": "TLE", "execution_time": "6000 ms", "memory": "147 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nimport qiskit.circuit.library as qis\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    bits = []\n    ones = []\n    for i in range(n-1, -1, -1):\n        if L & (1<<i) != 0:\n            bits += [(i, ones.copy(), 1)]\n            ones += [i]\n        else:\n            bits += [(i, ones.copy(), 0)]\n\n    for target, controls, bit in bits:\n        for lsb_ctrl_i in range(len(controls), 0, -1):\n\n            ctrl_subset = controls[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate,  ctrl_subset + [target])\n\n        if bit == 1:\n            left = 1<<target\n            right = (L % left) + 1\n\n            wanted_cos = (left/(left + right))**0.5\n            theta = math.acos(wanted_cos)*2\n\n            gate = qis.RXGate(theta=theta)\n            if len(controls) != 0:\n                gate = gate.control(num_ctrl_qubits=len(controls))\n            qc.append(gate, controls + [target])\n            \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 3, "result": "TLE", "execution_time": "6000 ms", "memory": "147 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nimport qiskit.circuit.library as qis\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    bits = []\n    ones = []\n    for i in range(n-1, -1, -1):\n        if L & (1<<i) != 0:\n            bits += [(i, len(ones), 1)]\n            ones += [i]\n        else:\n            bits += [(i, len(ones), 0)]\n\n    for target, up_to_i_controls, bit in bits:\n        for lsb_ctrl_i in range(up_to_i_controls, 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate,  ctrl_subset + [target])\n\n        if bit == 1:\n            controls = ones[0:up_to_i_controls]\n            left = 1<<target\n            right = (L % left) + 1\n\n            wanted_cos = (left/(left + right))**0.5\n            theta = math.acos(wanted_cos)*2\n\n            gate = qis.RXGate(theta=theta)\n            if len(controls) != 0:\n                gate = gate.control(num_ctrl_qubits=len(controls))\n            qc.append(gate, controls + [target])\n            \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 4, "result": "RE", "execution_time": "1406 ms", "memory": "140 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nimport qiskit.circuit.library as qis\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n def solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    ones = []\n\n    for target in range(n-1, -1, -1):\n        bit = L & (1<<target) != 0\n\n        for lsb_ctrl_i in range(len(ones), 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate,  ctrl_subset + [target])\n\n        if bit == 1:\n            left = 1<<target\n            right = (L % left) + 1\n\n            wanted_cos = (left/(left + right))**0.5\n            theta = math.acos(wanted_cos)*2\n\n            gate = qis.RXGate(theta=theta)\n            if len(ones) != 0:\n                gate = gate.control(num_ctrl_qubits=len(ones))\n            qc.append(gate, ones + [target])\n            \n            ones.append(target)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 5, "result": "RE", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nimport qiskit.circuit.library as qis\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n def solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    ones = []\n\n    for target in range(n-1, -1, -1):\n        bit = L & (1<<target) != 0\n\n        for lsb_ctrl_i in range(len(ones), 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate,  ctrl_subset + [target])\n\n        if bit == 1:\n            left = 1<<target\n            right = (L % left) + 1\n\n            wanted_cos = (left/(left + right))**0.5\n            theta = math.acos(wanted_cos)*2\n\n            gate = qis.RXGate(theta=theta)\n            if len(ones) != 0:\n                gate = gate.control(num_ctrl_qubits=len(ones))\n            qc.append(gate, ones + [target])\n            \n            ones.append(target)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 6, "result": "TLE", "execution_time": "6000 ms", "memory": "147 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nimport qiskit.circuit.library as qis\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    ones = []\n\n    for target in range(n-1, -1, -1):\n        bit = L & (1<<target) != 0\n\n        for lsb_ctrl_i in range(len(ones), 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate,  ctrl_subset + [target])\n\n        if bit == 1:\n            left = 1<<target\n            right = (L % left) + 1\n\n            wanted_cos = (left/(left + right))**0.5\n            theta = math.acos(wanted_cos)*2\n\n            gate = qis.RXGate(theta=theta)\n            if len(ones) != 0:\n                gate = gate.control(num_ctrl_qubits=len(ones))\n            qc.append(gate, ones + [target])\n            \n            ones.append(target)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 7, "result": "TLE", "execution_time": "6000 ms", "memory": "147 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nimport qiskit.circuit.library as qis\nimport numpy as np\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    ones = []\n    one_count = 0\n\n    inds = np.arange(n)\n    lefts = np.vectorize(lambda x: 1<<x)(inds)\n    wanted_coss = np.vectorize(lambda left: (left / (left + ((L%left) + 1))) ** 0.5)(lefts)\n    thetas = np.vectorize(lambda w: math.acos(w) * 2)(wanted_coss)\n\n\n    for target in range(n-1, -1, -1):\n        bit = L & (1<<target) != 0\n\n        for lsb_ctrl_i in range(len(ones), 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = qis.HGate().control(num_ctrl_qubits=len(ctrl_subset), ctrl_state=ctrl_state)\n\n            qc.append(gate, ctrl_subset + [target], copy=False)\n\n        if bit == 1:\n            theta = thetas[target]\n\n            gate = qis.RXGate(theta=theta)\n            if one_count != 0:\n                gate = gate.control(num_ctrl_qubits=one_count)\n\n            qc.append(gate, ones + [target], copy=False)\n            \n            ones.append(target)\n            one_count += 1\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 8, "result": "UGE", "execution_time": "1502 ms", "memory": "141 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RXGate\nimport numpy as np\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    ones = []\n    one_count = 0\n\n    inds = np.arange(n)\n    lefts = np.vectorize(lambda x: 1<<x)(inds)\n    wanted_coss = np.vectorize(lambda left: (left / (left + ((L%left) + 1))) ** 0.5)(lefts)\n    thetas = np.vectorize(lambda w: math.acos(w) * 2)(wanted_coss)\n\n\n    for target in range(n-1, -1, -1):\n        bit = L & (1<<target) != 0\n\n        for lsb_ctrl_i in range(one_count, 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            ctrl_state = (1<< (lsb_ctrl_i - 1)) - 1\n            gate = HGate().control(num_ctrl_qubits=lsb_ctrl_i, ctrl_state=ctrl_state, annotated=True)\n\n            qc.append(gate, ctrl_subset + [target], copy=False)\n\n        if bit == 1:\n            theta = thetas[target]\n\n            gate = RXGate(theta=theta)\n            if one_count != 0:\n                gate = gate.control(num_ctrl_qubits=one_count, annotated=True)\n\n            qc.append(gate, ones + [target], copy=False)\n            \n            ones.append(target)\n            one_count += 1\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3961B3E29FC", "submission_order": 9, "result": "TLE", "execution_time": "6000 ms", "memory": "147 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RXGate\nimport numpy as np\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L -= 1\n\n    ones = []\n    one_count = 0\n\n    inds = np.arange(n)\n    lefts = np.vectorize(lambda x: 1<<x)(inds)\n    wanted_coss = np.vectorize(lambda left: (left / (left + ((L%left) + 1))) ** 0.5)(lefts)\n    thetas = np.vectorize(lambda w: math.acos(w) * 2)(wanted_coss)\n\n    CHs = [HGate()] + [HGate().control(num_ctrl_qubits=i, ctrl_state=(1<<(i-1))-1)  for i in range(1, n)]\n\n    for target in range(n-1, -1, -1):\n        bit = L & (1<<target) != 0\n\n        for lsb_ctrl_i in range(len(ones), 0, -1):\n\n            ctrl_subset = ones[0:lsb_ctrl_i]\n\n            gate = CHs[lsb_ctrl_i]\n\n            qc.append(gate, ctrl_subset + [target])\n\n        if bit == 1:\n            theta = thetas[target]\n\n            gate = RXGate(theta=theta)\n            if one_count != 0:\n                gate = gate.control(num_ctrl_qubits=one_count)\n\n            qc.append(gate, ones + [target], copy=False)\n            \n            ones.append(target)\n            one_count += 1\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3BAEA132211", "submission_order": 1, "result": "WA", "execution_time": "1862 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    M = L\n    i = n-1\n    if (L>>i)&1 == 0:\n        qc.x(i)\n    else:\n        theta = -2*math.acos(math.sqrt(2**i/M))\n        qc.x(i)\n        qc.ry(theta,i)\n        CH = HGate().control(n-i)\n        for j in range(i):\n            qc.append(CH,list(range(n-1,i-1,-1))+[j])\n        qc.x(i)\n        M -= 2**i\n    for i in range(n-2,-1,-1):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n        else:\n            theta = -2*math.acos(math.sqrt(2**i/M))\n            qc.x(i)\n            qc.append(RYGate(theta).control(n-i-1),range(n-1,i-1,-1))\n            CH = HGate().control(n-i)\n            for j in range(i):\n                qc.append(CH,list(range(n-1,i-1,-1))+[j])\n            qc.x(i)\n            M -= 2**i\n        qc_copy = qc.copy()\n        for j in range(n-1,i-1,-1):\n            if (L>>j)&1 == 0:\n                qc_copy.x(j)\n    for i in range(n-1,-1,-1):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD3BAEA132211", "submission_order": 2, "result": "AC", "execution_time": "1943 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==(1<<n):\n        for i in range(n):\n            qc.h(i)\n    else:\n        M = L\n        i = n-1\n        if (L>>i)&1 == 0:\n            qc.x(i)\n        else:\n            theta = -2*math.acos(math.sqrt(2**i/M))\n            qc.x(i)\n            qc.ry(theta,i)\n            CH = HGate().control(n-i)\n            for j in range(i):\n                qc.append(CH,list(range(n-1,i-1,-1))+[j])\n            qc.x(i)\n            M -= 2**i\n        for i in range(n-2,-1,-1):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n            else:\n                theta = -2*math.acos(math.sqrt(2**i/M))\n                qc.x(i)\n                qc.append(RYGate(theta).control(n-i-1),range(n-1,i-1,-1))\n                CH = HGate().control(n-i)\n                for j in range(i):\n                    qc.append(CH,list(range(n-1,i-1,-1))+[j])\n                qc.x(i)\n                M -= 2**i\n            qc_copy = qc.copy()\n            for j in range(n-1,i-1,-1):\n                if (L>>j)&1 == 0:\n                    qc_copy.x(j)\n        for i in range(n-1,-1,-1):\n            if (L>>i)&1 == 0:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AD5933DFFB1E2", "submission_order": 1, "result": "RE", "execution_time": "1887 ms", "memory": "157 MiB", "code": "'''python\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 2**n:\n        for i in range(n):\n            qc.h(i)\n    else:\n        L_code = format(L, f'0{n}b')\n        m = [n-1-i for i in range(n) if L_code[i] == \"1\"]\n        l = [L]\n        for i in range(len(m)-1):\n            l.append(l[-1]-2**m[i])\n        qc.x(m[0])\n        for i in range(len(m)-1):\n            split_one_hot(qc,m[i],m[i+1],2**m[i]/l[i])\n        for i in range(n-1,-1,-1):\n            if i in m and i !=0:\n                qc.append(multi_ch(i,n), qargs=range(n-1,-1,-1))\n            qc.x(i)\n        for i in range(n-1,-1,-1):\n            if L_code[i] == \"0\":\n                if i != 0:\n                    qc.append(XGate().control(i),qargs=range(n-1,n-2-i,-1))\n                else:\n                    qc.x(n-1-i)\n        print(m,l)\n    return qc\n\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n\ndef multi_ch(i,n):\n    # Hゲートだけのサブ回路作成\n    qch = QuantumCircuit(i)\n    for j in range(i):\n        qch.h(j)\n    \n    # ゲート化 → 多重制御化\n    h_gate = qch.to_gate()\n    print(n-i-1)\n    controlled_h_gate = h_gate.control(n-i)\n    return controlled_h_gate\n'''"}
{"problem": "QPC001_C2", "user": "AD5933DFFB1E2", "submission_order": 2, "result": "AC", "execution_time": "2982 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L == 2**n:\n        for i in range(n):\n            qc.h(i)\n    else:\n        L_code = format(L, f'0{n}b')\n        m = [n-1-i for i in range(n) if L_code[i] == \"1\"]\n        l = [L]\n        for i in range(len(m)-1):\n            l.append(l[-1]-2**m[i])\n        qc.x(m[0])\n        for i in range(len(m)-1):\n            split_one_hot(qc,m[i],m[i+1],2**m[i]/l[i])\n        for i in range(n-1,-1,-1):\n            if i in m and i !=0:\n                qc.append(multi_ch(i,n), qargs=range(n-1,-1,-1))\n            qc.x(i)\n        for i in range(n-1,-1,-1):\n            if L_code[i] == \"0\":\n                if i != 0:\n                    qc.append(XGate().control(i),qargs=range(n-1,n-2-i,-1))\n                else:\n                    qc.x(n-1-i)\n        print(m,l)\n    return qc\n\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n\ndef multi_ch(i,n):\n    # Hゲートだけのサブ回路作成\n    qch = QuantumCircuit(i)\n    for j in range(i):\n        qch.h(j)\n    \n    # ゲート化 → 多重制御化\n    h_gate = qch.to_gate()\n    print(n-i-1)\n    controlled_h_gate = h_gate.control(n-i)\n    return controlled_h_gate\n'''"}
{"problem": "QPC001_C2", "user": "AD9280603CD8A", "submission_order": 1, "result": "AC", "execution_time": "3806 ms", "memory": "103 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate\nfrom qiskit.circuit.library import RYGate\nimport math\ndef solve(n: int, L: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  L2 = L\n  for i in range(n - 1, -1, -1):\n    if L2 > (1 << i):\n      print(i)\n      for j in range(i + 1, n):\n        if (((L - 1) >> j) & 1) == 0:\n          qc.x(j)\n      theta = math.atan2(math.sqrt(L2 - (1 << i)), math.sqrt(1 << i)) * 2\n      if i == n - 1:\n        qc.ry(theta, n - 1)\n      else:\n        qc.append(RYGate(theta).control(n - 1 - i), list(range(i + 1, n)) + [i])\n      qc.x(i)\n      for j in range(i):\n        qc.append(HGate().control(n - i), list(range(i, n)) + [j])\n      qc.x(i)\n      L2 = L2 - (1 << i)\n      for j in range(i + 1, n):\n        if (((L - 1) >> j) & 1) == 0:\n          qc.x(j)\n  return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 1, "result": "UGE", "execution_time": "1703 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 量子状態の次元は 2^n なので、状態ベクトルの長さは 2**n となる\n    dim = 2 ** n\n    \n    # 状態ベクトルを初期化\n    # i = 0, 1, ..., L-1 の各成分に 1/sqrt(L) を設定し、\n    # それ以外の成分は 0 とする。\n    # これにより、目的の状態\n    # |ψ⟩ = (1/√L) (|0⟩ + |1⟩ + ... + |L-1⟩)\n    # が得られる\n    state = [0.0] * dim\n    amp = 1 / np.sqrt(L)\n    for i in range(L):\n        state[i] = amp\n\n    # 初期状態から目的の状態へ初期化する\n    # Qiskit ではデフォルトでリトルエンディアンとなっているため、\n    # list(range(n)) で各量子ビットを指定する\n    qc.initialize(state, list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import StatePreparation\nimport numpy as np\n \n \ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # 2^n 次元の状態ベクトルを用意する．\n    # 添字 i = 0,1,...,L-1 に対して振幅 1/sqrt(L) を与え，\n    # i >= L の部分は 0 とする．\n    dim = 2 ** n\n    state = np.zeros(dim, dtype=complex)\n    amp = 1 / np.sqrt(L)\n    for i in range(L):\n        state[i] = amp\n    \n    # StatePreparation クラスは内部で Möttönen型のアルゴリズムにより\n    # 標準ゲート（Ry, Rz, CNOT など）を用いた回路へ分解される．\n    # これにより，Initialize などの禁止ゲートを使うことなく目的の状態を作る．\n    sp = StatePreparation(state)\n    qc.append(sp, qc.qubits)\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate\nimport math\nimport itertools\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 量子ビットの番号は 0～n-1，\n    # リトルエンディアンでは整数値は ∑_{j=0}^{n-1} 2^j * (qubit j の値) として読む\n\n    # ここでは，最も重みの大きい qubit（番号 n-1）から順に回転を設定する\n    for k in range(n-1, -1, -1):\n        # 上位ビットとして制御する qubit の集合は {q_{k+1},...,q_{n-1}}\n        control_indices = list(range(k+1, n))\n        # 制御対象の上位ビットの割り当て（分岐）をすべて走査\n        for prefix in itertools.product([0, 1], repeat=len(control_indices)):\n            # prefix に対応して，上位ビットが取る値により整数値への寄与は\n            # P = ∑_{j in control_indices} (bit_j * 2^j)\n            P = 0\n            for ctrl, bit in zip(control_indices, prefix):\n                P += bit * (2 ** ctrl)\n            # 現在決定する qubitは q_k の重み 2^k で寄与する\n            # 下位（q_{0}～q_{k-1}）で作れる状態数は 2^k 個\n            # よって，q_k に 0 を割り当てた場合の有効状態数は\n            if P >= L:\n                N0 = 0\n            else:\n                N0 = min(2 ** k, L - P)\n            # q_k に 1 を割り当てた場合は，寄与が 2^k 加わるので\n            if P + (2 ** k) >= L:\n                N1 = 0\n            else:\n                N1 = min(2 ** k, L - (P + (2 ** k)))\n            N_total = N0 + N1\n            # もしこの分岐で有効な状態がなければスキップ\n            if N_total == 0:\n                continue\n            # 回転角は，理想的には\n            # cos(θ/2) = √(N0/(N0+N1))，すなわち θ = 2·arccos(√(N0/N_total))\n            # ただし，N0=0 のときは θ = π，また N1=0 のときは θ = 0 とする\n            if N0 == 0:\n                theta = math.pi\n            elif N1 == 0:\n                theta = 0.0\n            else:\n                theta = 2 * math.acos(math.sqrt(N0 / N_total))\n            # 角度が 0 ならゲート不要\n            if abs(theta) < 1e-10:\n                continue\n\n            # 制御付き RY ゲートを作成\n            base_gate = RYGate(theta)\n            num_controls = len(control_indices)\n            if num_controls > 0:\n                controlled_gate = base_gate.control(num_controls)\n                # デフォルトでは制御は「|1>」の場合に作用するため，\n                # 制御すべき値が 0 のときは X ゲートで反転させる\n                for ctrl, bit in zip(control_indices, prefix):\n                    if bit == 0:\n                        qc.x(ctrl)\n                # 制御 qubit（上位ビット）＋対象 qubit q_k の順番で追加\n                qc.append(controlled_gate, control_indices + [k])\n                for ctrl, bit in zip(control_indices, prefix):\n                    if bit == 0:\n                        qc.x(ctrl)\n            else:\n                # 制御 qubitがない場合は単純に RY ゲートを適用\n                qc.append(base_gate, [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 4, "result": "RE", "execution_time": "1410 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 量子ビットの番号は 0～n-1，\n    # リトルエンディアンでは整数値は ∑_{j=0}^{n-1} 2^j * (qubit j の値) として読む\n\n    # ここでは，最も重みの大きい qubit（番号 n-1）から順に回転を設定する\n    for k in range(n-1, -1, -1):\n        # 上位ビットとして制御する qubit の集合は {q_{k+1},...,q_{n-1}}\n        control_indices = list(range(k+1, n))\n        # 制御対象の上位ビットの割り当て（分岐）をすべて走査\n        for prefix in itertools.product([0, 1], repeat=len(control_indices)):\n            # prefix に対応して，上位ビットが取る値により整数値への寄与は\n            # P = ∑_{j in control_indices} (bit_j * 2^j)\n            P = 0\n            for ctrl, bit in zip(control_indices, prefix):\n                P += bit * (2 ** ctrl)\n            # 現在決定する qubitは q_k の重み 2^k で寄与する\n            # 下位（q_{0}～q_{k-1}）で作れる状態数は 2^k 個\n            # よって，q_k に 0 を割り当てた場合の有効状態数は\n            if P >= L:\n                N0 = 0\n            else:\n                N0 = min(2 ** k, L - P)\n            # q_k に 1 を割り当てた場合は，寄与が 2^k 加わるので\n            if P + (2 ** k) >= L:\n                N1 = 0\n            else:\n                N1 = min(2 ** k, L - (P + (2 ** k)))\n            N_total = N0 + N1\n            # もしこの分岐で有効な状態がなければスキップ\n            if N_total == 0:\n                continue\n            # 回転角は，理想的には\n            # cos(θ/2) = √(N0/(N0+N1))，すなわち θ = 2·arccos(√(N0/N_total))\n            # ただし，N0=0 のときは θ = π，また N1=0 のときは θ = 0 とする\n            if N0 == 0:\n                theta = math.pi\n            elif N1 == 0:\n                theta = 0.0\n            else:\n                theta = 2 * math.acos(math.sqrt(N0 / N_total))\n            # 角度が 0 ならゲート不要\n            if abs(theta) < 1e-10:\n                continue\n\n            # 制御付き RY ゲートを作成\n            base_gate = RYGate(theta)\n            num_controls = len(control_indices)\n            if num_controls > 0:\n                controlled_gate = base_gate.control(num_controls)\n                # デフォルトでは制御は「|1>」の場合に作用するため，\n                # 制御すべき値が 0 のときは X ゲートで反転させる\n                for ctrl, bit in zip(control_indices, prefix):\n                    if bit == 0:\n                        qc.x(ctrl)\n                # 制御 qubit（上位ビット）＋対象 qubit q_k の順番で追加\n                qc.append(controlled_gate, control_indices + [k])\n                for ctrl, bit in zip(control_indices, prefix):\n                    if bit == 0:\n                        qc.x(ctrl)\n            else:\n                # 制御 qubitがない場合は単純に RY ゲートを適用\n                qc.append(base_gate, [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 5, "result": "DLE", "execution_time": "2419 ms", "memory": "172 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # リトルエンディアン：整数は q_0 が最下位ビットとして解釈される\n\n    # k: 現在制御対象とする qubit（重み 2^k）のインデックス．\n    # 上位ビットは q_{k+1}, ..., q_{n-1} となるため，k は n-1 から 0 まで走査する\n    for k in range(n-1, -1, -1):\n        # 上位ビットのインデックス\n        control_indices = list(range(k+1, n))\n        num_controls = len(control_indices)\n        # control_indices に対応する全割り当て（ビット列）を生成する．\n        # itertools.product を使わず，0 から 2^(num_controls)-1 までの整数の2進数表現を用いる\n        if num_controls == 0:\n            prefixes = [[]]\n        else:\n            prefixes = []\n            for x in range(2 ** num_controls):\n                prefix = []\n                # 桁数は num_controls．\n                # 制御ビットの順序は control_indices の順序と合わせるため，\n                # 最上位桁から順に取り出す\n                for i in range(num_controls):\n                    # i = 0 で最上位ビット，i = num_controls-1 で最下位ビットとなるようにする\n                    bit = (x >> (num_controls - 1 - i)) & 1\n                    prefix.append(bit)\n                prefixes.append(prefix)\n        # 各分岐（上位ビットの特定の割り当て）ごとに，\n        # q_k に適用する制御付き RY ゲートを決定する\n        for prefix in prefixes:\n            # 上位ビットが与える整数値 P = sum_{j in control_indices} (bit_j * 2^j)\n            P = 0\n            for ctrl, bit in zip(control_indices, prefix):\n                P += bit * (2 ** ctrl)\n            # q_k の重みは 2^k\n            # q_k に 0 を割り当てた場合の，有効な状態数 N0:\n            if P >= L:\n                N0 = 0\n            else:\n                N0 = min(2 ** k, L - P)\n            # q_k に 1 を割り当てた場合の，有効な状態数 N1:\n            if P + (2 ** k) >= L:\n                N1 = 0\n            else:\n                N1 = min(2 ** k, L - (P + (2 ** k)))\n            N_total = N0 + N1\n            if N_total == 0:\n                continue\n            # 回転角 θ を決定する．\n            # 特に，N0 == 0 のときは θ = π，N1 == 0 のときは θ = 0 とする．\n            if N0 == 0:\n                theta = math.pi\n            elif N1 == 0:\n                theta = 0.0\n            else:\n                theta = 2 * math.acos(math.sqrt(N0 / N_total))\n            # 角度が 0 に近ければゲートを省略\n            if abs(theta) < 1e-10:\n                continue\n            base_gate = RYGate(theta)\n            if num_controls > 0:\n                # 制御付きゲートを作成\n                controlled_gate = base_gate.control(num_controls)\n                # 標準では制御が |1⟩ のときに作用するため，\n                # 制御すべき値が 0 の場合は前後に X ゲートを挿入する\n                for ctrl, bit in zip(control_indices, prefix):\n                    if bit == 0:\n                        qc.x(ctrl)\n                qc.append(controlled_gate, control_indices + [k])\n                for ctrl, bit in zip(control_indices, prefix):\n                    if bit == 0:\n                        qc.x(ctrl)\n            else:\n                # 制御ビットがなければ，そのまま RY ゲートを適用\n                qc.append(base_gate, [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 6, "result": "TLE", "execution_time": "3000 ms", "memory": "187 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate, HGate\nimport math\n\n# 補助関数：サブ回路の各命令を「制御付き」にしてメイン回路 qc に追加する\ndef add_controlled_subcircuit(qc, subcircuit, control_qubit, target_qubits, control_value):\n    # 制御すべき値が 0 の場合は、前後に X を入れて反転制御とする\n    if control_value == 0:\n        qc.x(control_qubit)\n    # サブ回路に含まれる各命令について\n    for instr, qargs, _ in subcircuit.data:\n        # サブ回路内の量子ビットの位置を target_qubits に対応付ける\n        new_qargs = []\n        for q in qargs:\n            idx = subcircuit.qubits.index(q)\n            new_qargs.append(target_qubits[idx])\n        # 制御付き版のゲートを作成（1 つの制御を追加）\n        controlled_gate = instr.control(1)\n        # 制御 qubit を先頭に、対象 qubit をその後に指定して追加\n        qc.append(controlled_gate, [control_qubit] + new_qargs)\n    if control_value == 0:\n        qc.x(control_qubit)\n\n# 再帰的に、指定された量子ビット集合 q_list 上で\n# 状態 |ψ⟩ = 1/√L ∑_{i=0}^{L-1} |i⟩ (リトルエンディアン) を作る回路を返す\ndef prepare_state(q_list, L):\n    n = len(q_list)\n    qc = QuantumCircuit(n)\n    if n == 0:\n        return qc\n    # 1量子ビットの場合\n    if n == 1:\n        if L == 1:\n            # 状態 |0⟩ のままでよい\n            return qc\n        elif L == 2:\n            # (|0⟩+|1⟩)/√2 を作る → H ゲート\n            qc.h(q_list[0])\n            return qc\n    # もし L = 2^n なら全状態に均一振幅 → 各 qubit に H\n    if L == 2**n:\n        for q in q_list:\n            qc.h(q)\n        return qc\n\n    # n ≥ 2 かつ L < 2^n の場合\n    # q_list の最後の量子ビットを MSB (q_m)、残りを下位 (Q_low) とする\n    N_low = 2**(n-1)\n    if L <= N_low:\n        # 下位側だけに状態が存在する → q_m は |0⟩ のまま、\n        # 下位 n-1 量子ビットで問題を再帰的に解く\n        sub_qc = prepare_state(q_list[:-1], L)\n        qc.compose(sub_qc, qubits=range(n-1), inplace=True)\n        return qc\n    else:\n        # L > N_low なら、ブロック分割\n        L0 = N_low         # q_m=0 側に対応する状態数（0～2^(n-1)-1）\n        L1 = L - N_low     # q_m=1 側（残り）の状態数\n        # q_m に対して、以下を満たすよう RY 回転を適用\n        #   cos(θ/2)=√(L0/L), sin(θ/2)=√(L1/L)\n        theta = 2 * math.acos(math.sqrt(L0 / L))\n        qc.ry(theta, q_list[-1])\n        # --- 下位側の回路を条件付きで適用 ---\n        # branch 0 (q_m = 0)：下位側は「全状態（2^(n-1) 個）」＝ uniform\n        uniform = QuantumCircuit(n-1)\n        for i in range(n-1):\n            uniform.h(uniform.qubits[i])\n        # branch 1 (q_m = 1)：下位側を再帰的に L1 個の状態に準備\n        rec = prepare_state(list(range(n-1)), L1)\n        # controlled subcircuit を追加\n        # まず、q_m が 1 のときに rec を適用\n        add_controlled_subcircuit(qc, rec, control_qubit=q_list[-1], target_qubits=q_list[:-1], control_value=1)\n        # 次に、q_m が 0 のときに uniform を適用\n        add_controlled_subcircuit(qc, uniform, control_qubit=q_list[-1], target_qubits=q_list[:-1], control_value=0)\n        return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 特別ケース：もし L = 2^n なら全状態に均一 →各 qubitに H を適用\n    if L == 2**n:\n        for q in range(n):\n            qc.h(q)\n        return qc\n    # 再帰的状態準備回路を作成（リトルエンディアン：qubit 0 が LSB，qubit n-1 が MSB）\n    prep = prepare_state(list(range(n)), L)\n    qc.compose(prep, qubits=range(n), inplace=True)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 7, "result": "TLE", "execution_time": "3000 ms", "memory": "176 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate, HGate\nimport math\n\n# サブ回路を一括で制御付き化する補助関数\ndef add_controlled_subcircuit(qc, subcircuit, control_qubit, target_qubits, control_value):\n    # subcircuit をゲート化して一括制御付きゲートに変換\n    gate = subcircuit.to_gate()\n    controlled_gate = gate.control(1)\n    if control_value == 0:\n        qc.x(control_qubit)\n    qc.append(controlled_gate, [control_qubit] + target_qubits)\n    if control_value == 0:\n        qc.x(control_qubit)\n\n# memo[(n, L)] に対して既に作成した回路を記憶する\nmemo = {}\n\n# n 量子ビット上で、状態 |ψ⟩ = 1/√L ∑_{i=0}^{L-1} |i⟩ を作る回路（ローカル回路）を返す関数\ndef prepare_state(n, L):\n    if (n, L) in memo:\n        return memo[(n, L)]\n    qc = QuantumCircuit(n)\n    if n == 0:\n        memo[(n, L)] = qc\n        return qc\n    # 1量子ビットの場合\n    if n == 1:\n        if L == 1:\n            memo[(n, L)] = qc  # |0⟩ のままでよい\n            return qc\n        elif L == 2:\n            qc.h(0)         # (|0⟩+|1⟩)/√2\n            memo[(n, L)] = qc\n            return qc\n    # すべての状態が有効なら、各 qubit に H を適用\n    if L == 2**n:\n        for i in range(n):\n            qc.h(i)\n        memo[(n, L)] = qc\n        return qc\n\n    # n ≥ 2 かつ L < 2^n の場合\n    # ※ローカル回路では qubit 0～n-2 を下位、qubit n-1 を MSB とする（リトルエンディアン）\n    if L <= 2**(n-1):\n        # 有効な状態は下位側にすべて含まれる：MSBは |0⟩ のまま\n        sub = prepare_state(n-1, L)\n        qc.compose(sub, qubits=list(range(n-1)), inplace=True)\n        memo[(n, L)] = qc\n        return qc\n    else:\n        # L > 2^(n-1)\n        L0 = 2**(n-1)        # branch q_{n-1} = 0 側の状態数\n        L1 = L - L0          # branch q_{n-1} = 1 側の状態数\n        # q_{n-1} に対して RY 回転： cos(θ/2)=√(L0/L), sin(θ/2)=√(L1/L)\n        theta = 2 * math.acos(math.sqrt(L0 / L))\n        qc.ry(theta, n-1)\n        # branch 1 (q_{n-1} = 1)：下位 n-1 量子ビットで再帰的に L1 個の状態を作る\n        rec = prepare_state(n-1, L1)\n        add_controlled_subcircuit(qc, rec, control_qubit=n-1, target_qubits=list(range(n-1)), control_value=1)\n        # branch 0 (q_{n-1} = 0)：下位 n-1 量子ビットで全状態（2^(n-1) 個）を均一に作る\n        uniform = QuantumCircuit(n-1)\n        for i in range(n-1):\n            uniform.h(i)\n        add_controlled_subcircuit(qc, uniform, control_qubit=n-1, target_qubits=list(range(n-1)), control_value=0)\n        memo[(n, L)] = qc\n        return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    global memo\n    memo = {}  # 各呼び出しでメモをリセット\n    # 特別ケース：全状態が有効なら各 qubit に H を適用\n    if L == 2**n:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n        return qc\n    # 再帰的状態準備回路（ローカル回路）をそのまま返す\n    qc = prepare_state(n, L)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 8, "result": "RE", "execution_time": "1464 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # controlled_gate_cache のキーは (num_controls, rounded_theta) で、  \n    # 値は対応する controlled-RY ゲート\n    controlled_gate_cache = {}\n    # 事前に 2^i を計算しておく（i=0,...,n）\n    pows = [1 << i for i in range(n+1)]  # 1<<i は 2^i\n    \n    # 量子ビットの番号は 0～n-1（リトルエンディアン：qubit 0 が最下位）\n    # k を MSB側からLSB側へ（n-1 から 0）順に処理\n    for k in range(n-1, -1, -1):\n        # 上位（MSB側）の qubit のリスト（制御に使う）\n        control_indices = list(range(k+1, n))\n        num_controls = len(control_indices)\n        # 上位ビットの全割り当てを作成（itertools を使わずに 0～2^(num_controls)-1 でループ）\n        if num_controls == 0:\n            prefixes = [[]]\n        else:\n            num_prefixes = 1 << num_controls\n            prefixes = []\n            for x in range(num_prefixes):\n                prefix = []\n                for i in range(num_controls):\n                    # 上位桁から順に取り出す\n                    bit = (x >> (num_controls - 1 - i)) & 1\n                    prefix.append(bit)\n                prefixes.append(prefix)\n        # 各分岐について回転角を計算し、controlled-RY ゲートを追加\n        for prefix in prefixes:\n            # 上位ビット（control_indices）の割り当てから整数 P を計算  \n            # P = ∑_{ctrl in control_indices} (bit × 2^(ctrl))\n            P = 0\n            for ctrl, bit in zip(control_indices, prefix):\n                P += bit * (1 << ctrl)\n            # 現在対象とする qubit k の重みは 2^k\n            if P >= L:\n                N0 = 0\n            else:\n                N0 = min(pows[k], L - P)\n            if P + pows[k] >= L:\n                N1 = 0\n            else:\n                N1 = min(pows[k], L - (P + pows[k]))\n            N_total = N0 + N1\n            if N_total == 0:\n                continue\n            # 回転角 θ を決定  \n            # ・もし N0 == 0 なら、θ = π（必ず 1 を選ぶ）  \n            # ・もし N1 == 0 なら、θ = 0（変化なし）  \n            # ・それ以外なら、cos(θ/2) = √(N0/N_total)\n            if N0 == 0:\n                theta = math.pi\n            elif N1 == 0:\n                theta = 0.0\n            else:\n                ratio = N0 / N_total\n                # 浮動小数点の誤差対策\n                if ratio < 0: ratio = 0\n                if ratio > 1: ratio = 1\n                theta = 2 * math.acos(math.sqrt(ratio))\n            if abs(theta) < 1e-10:\n                continue\n            # controlled-RY ゲートのキャッシュキー\n            key = (num_controls, round(theta, 12))\n            if key in controlled_gate_cache:\n                controlled_gate = controlled_gate_cache[key]\n            else:\n                controlled_gate = RYGate(theta).control(num_controls)\n                controlled_gate_cache[key] = controlled_gate\n            # 制御付きの場合、標準では制御が |1⟩ で作用するため、  \n            # 制御すべきビットが 0 の場合は X ゲートを前後に挿入して反転制御とする\n            if num_controls > 0:\n                for ctrl, bit in zip(control_indices, prefix):\n                    if bit == 0:\n                        qc.x(ctrl)\n                qc.append(controlled_gate, control_indices + [k])\n                for ctrl, bit in zip(control_indices, prefix):\n                    if bit == 0:\n                        qc.x(ctrl)\n            else:\n                qc.append(RYGate(theta), [k])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 9, "result": "TLE", "execution_time": "3000 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef prepare_uniform(n, L):\n    \"\"\"\n    n 量子ビット上で、状態\n      |ψ⟩ = 1/√L ∑_{i=0}^{L-1} |i⟩\n    （リトルエンディアン: qubit 0 が LSB, qubit n-1 が MSB）\n    を作る QuantumCircuit を返す。\n    \"\"\"\n    qc = QuantumCircuit(n)\n    if n == 0:\n        return qc\n    # 1量子ビットの場合\n    if n == 1:\n        if L == 1:\n            return qc  # |0⟩ のまま\n        elif L == 2:\n            qc.h(0)   # (|0⟩+|1⟩)/√2\n            return qc\n    # 全状態が有効なら、すべての qubit に H を適用\n    if L == 2**n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n\n    # ここから n ≥ 2 かつ L < 2^n の場合\n    m = 2**(n-1)  # 下位 n-1 量子ビットで作れる状態数\n    if L <= m:\n        # 有効な状態は MSB = 0 側にのみ存在\n        sub = prepare_uniform(n-1, L)\n        qc.compose(sub, qubits=list(range(n-1)), inplace=True)\n        # MSB (qubit n-1) はそのまま |0⟩ のまま\n        return qc\n    else:\n        # L > m の場合\n        L0 = m         # MSB = 0 側の状態数（全ての状態）\n        L1 = L - m     # MSB = 1 側の状態数\n        # MSB (qubit n-1) に対して RY 回転を適用\n        theta = 2 * math.acos(math.sqrt(L0 / L))\n        qc.ry(theta, n-1)\n        # branch for MSB = 0: 下位 n-1 量子ビットに対して「全状態の均一状態」\n        qc0 = QuantumCircuit(n-1)\n        for i in range(n-1):\n            qc0.h(i)\n        # branch for MSB = 1: 下位 n-1 量子ビットに対して再帰的に L1 個の状態を作る\n        qc1 = prepare_uniform(n-1, L1)\n        # 制御付きゲートとしてまとめる（.to_gate() を用いて一括で制御付きに）\n        gate1 = qc1.to_gate()\n        cgate1 = gate1.control(1)\n        gate0 = qc0.to_gate()\n        cgate0 = gate0.control(1)\n        # branch 1: MSB が |1⟩ のときに下位に qc1 を適用（制御が |1⟩ でそのまま作用）\n        qc.append(cgate1, [n-1] + list(range(n-1)))\n        # branch 0: MSB が |0⟩ のときに下位に qc0 を適用（制御が |0⟩ となるよう、前後に X を挿入）\n        qc.x(n-1)\n        qc.append(cgate0, [n-1] + list(range(n-1)))\n        qc.x(n-1)\n        return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    入力:\n      n: 量子ビット数\n      L: 有効な状態数（1 ≤ L ≤ 2^n）\n    出力:\n      測定時に状態 |0⟩, |1⟩, ..., |L-1⟩ が等確率で観測される状態\n      |ψ⟩ = 1/√L ∑_{i=0}^{L-1} |i⟩ を作り出す QuantumCircuit\n    \"\"\"\n    qc = QuantumCircuit(n)\n    # 特別ケース：全状態が有効なら各 qubit に H を適用\n    if L == 2**n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    # 再帰的状態準備回路を生成し、メイン回路に合成\n    prep = prepare_uniform(n, L)\n    qc.compose(prep, qubits=range(n), inplace=True)\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 10, "result": "DLE", "execution_time": "1587 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate\nimport math\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # controlled_gate_cache のキーは (num_controls, rounded_theta)\n    controlled_gate_cache = {}\n    # 事前に 2^(i) を計算（i=0,...,n）\n    pows = [1 << i for i in range(n+1)]\n    \n    # レベル k = 0,...,n-1 について処理する\n    # ※レベル 0 →接頭辞は空（1 通り）：このときターゲットは qubit n-1（MSB）\n    # レベル k のとき、接頭辞の長さは k、対象の qubitは q_{n-1-k}、制御 qubitは q_{n-1},…,q_{n-k}\n    for k in range(0, n):\n        target = n - 1 - k\n        num_controls = k  # 接頭辞の長さ\n        num_prefixes = 1 << k  # 2^k 通り\n        for b in range(num_prefixes):\n            # ノードの offset = b * 2^(n-k)\n            offset = b * (1 << (n - k))\n            if offset >= L:\n                continue  # この枝は全て零\n            width = 1 << (n - k)\n            half = 1 << (n - k - 1)  # 2^(n-k-1)\n            # 左側の非零葉数\n            left_count = min(half, L - offset) if offset < L else 0\n            # 右側の非零葉数\n            if offset + half < L:\n                right_count = min(half, L - (offset + half))\n            else:\n                right_count = 0\n            # 回転角の決定\n            if left_count == 0:\n                theta = math.pi\n            elif right_count == 0:\n                theta = 0.0\n            else:\n                theta = 2 * math.atan(math.sqrt(right_count / left_count))\n            if abs(theta) < 1e-10:\n                continue  # わずかな回転ならスキップ\n            \n            if num_controls == 0:\n                # 制御が不要の場合：単にターゲット qubitに RY を適用\n                qc.ry(theta, target)\n            else:\n                key = (num_controls, round(theta, 12))\n                if key in controlled_gate_cache:\n                    controlled_ry = controlled_gate_cache[key]\n                else:\n                    base_gate = RYGate(theta)\n                    controlled_ry = base_gate.control(num_controls)\n                    controlled_gate_cache[key] = controlled_ry\n                # 制御 qubitのリスト（順序は: q_{n-1}, q_{n-2}, …, q_{n-k}）\n                controls = [n - 1 - i for i in range(num_controls)]\n                # 接頭辞 b の各桁（長さ k）のうち、値が 0 の場合は X ゲートで反転\n                for i in range(num_controls):\n                    desired = (b >> (k - 1 - i)) & 1\n                    if desired == 0:\n                        qc.x(controls[i])\n                # 制御付きゲートを追加\n                qc.append(controlled_ry, controls + [target])\n                # 反転用の X ゲートを元に戻す\n                for i in range(num_controls):\n                    desired = (b >> (k - 1 - i)) & 1\n                    if desired == 0:\n                        qc.x(controls[i])\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 11, "result": "TLE", "execution_time": "3000 ms", "memory": "191 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef prepare_state_be(n: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    大端（big‐endian）表現で、n 量子ビット上に\n      |ψ⟩ = (1/√L) ∑_{i=0}^{L-1} |i⟩\n    （ただし、i は 0～2^n-1 のうち、i < L のものにのみ非零振幅）\n    を作る回路を再帰的に構成する。\n    ※ここでは、量子回路の 0 番目の qubit を MSB として扱う。\n    \"\"\"\n    qc = QuantumCircuit(n)\n    if n == 0:\n        return qc\n    # 1量子ビットの場合\n    if n == 1:\n        if L == 1:\n            # |0>\n            return qc\n        elif L == 2:\n            # (|0>+|1>)/√2\n            qc.h(0)\n            return qc\n\n    # 2^({n-1}) を T とする\n    T = 1 << (n - 1)  # 2^(n-1)\n    L0 = L if L < T else T         # 数は min(L, 2^(n-1))\n    L1 = L - L0                   # 残り（L1 は 0 の場合もあり）\n    p0 = L0 / L\n    # R_y 回転の角度 θ で、cos(θ/2)=√p0, sin(θ/2)=√(1-p0)\n    theta = 2 * math.acos(math.sqrt(p0))\n    qc.ry(theta, 0)  # 0 番目（MSB）に適用\n\n    # 残り n-1 量子ビットは、qubits 1...n-1\n    if L0 > 0:\n        # branch for MSB = 0 : 対象は下位部分で i in {0, ..., L0-1}\n        sub0 = prepare_state_be(n - 1, L0)\n        # 制御が 0 で作用するようにする：X を前後に入れる\n        qc.x(0)\n        qc.append(sub0.to_gate().control(1), [0] + list(range(1, n)))\n        qc.x(0)\n    if L1 > 0:\n        # branch for MSB = 1 : 対象は下位部分で i in {0, ..., L1-1}\n        sub1 = prepare_state_be(n - 1, L1)\n        qc.append(sub1.to_gate().control(1), [0] + list(range(1, n)))\n    return qc\n\ndef reverse_qubits(qc: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    量子回路 qc の qubit の順序を反転（SWAP を用いてリトルエンディアンにする）。\n    ここでは、qc.qubits[0] を最下位とするリトルエンディアンに変換する。\n    \"\"\"\n    n = qc.num_qubits\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    入力: 量子ビット数 n, 有効な状態数 L (1 ≤ L ≤ 2^n)\n    出力: 測定時に、状態 |0>, |1>, …, |L-1> が等確率で観測され、\n         かつ振幅の二乗和が 1（正規化済み）の状態 |ψ⟩ を作る回路。\n         \n    ※内部では、大端表現で状態準備を行い、最後に SWAP でリトルエンディアンに変換する。\n    \"\"\"\n    # 特別ケース：L == 2^n なら単に各 qubit に H を適用\n    if L == (1 << n):\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n        return qc\n\n    # まず、大端表現で状態準備回路を作る\n    qc_be = prepare_state_be(n, L)\n    # 次に、qubit の順序を反転してリトルエンディアンにする\n    qc_le = reverse_qubits(qc_be)\n    return qc_le\n'''"}
{"problem": "QPC001_C2", "user": "AE70FFAA589E6", "submission_order": 12, "result": "WA", "execution_time": "2039 ms", "memory": "165 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # まず，対象となる状態ベクトル (長さ 2^n) を\n    # little–endianで「i < L なら1/sqrt(L)，それ以外は 0」と定義する．\n    # しかし，uniformly–controlled rotation のアルゴリズムは\n    # 回路中で big–endian順（すなわち反転した順番）の状態を作るので，\n    # ここではまず psi_big[j] = 1/sqrt(L)  if bit_reverse(j) < L, else 0\n    # と定義する．bit_reverse(j) は n–bit の j のビット反転．\n    N = 2**n\n    psi_big = [0.0] * N\n    for j in range(N):\n        # bit–reverse: j の n–bit 表現のビット順を反転する\n        rev = 0\n        temp = j\n        for _ in range(n):\n            rev = (rev << 1) | (temp & 1)\n            temp //= 2\n        if rev < L:\n            psi_big[j] = 1.0 / math.sqrt(L)\n        else:\n            psi_big[j] = 0.0\n\n    # uniformly–controlled Ry のアルゴリズム\n    # 以下のループは，k=0,1,...,n–1 で，\n    # それぞれ「対象ワイヤ target = n-k-1 に，\n    # 以前に処理した（上位）ワイヤの状態 j（k–bit文字列）に対して，\n    # 角度 theta(j) = 2 arccos sqrt( (sum_{l=0}^{2^(n-k-1)-1}|a_{j*2^(n-k)+l}|^2)\n    #                           /(sum_{l=0}^{2^(n-k)-1}|a_{j*2^(n-k)+l}|^2 ) )\n    # を用いた Ry を適用する」というものです．\n    #\n    # 注意: ここでは制御付きゲートは「通常制御が 1 のとき作動する」ので，\n    # もし制御ビットに対応する j のビットが 0 であれば，\n    # そのビットに対して X–ゲートを前後に適用しています．\n    for k in range(n):\n        step = 2 ** (n - k)      # ブロックの長さ\n        half = 2 ** (n - k - 1)    # ブロック前半の長さ\n        # k 進段では，j = 0,...,2^k - 1 の各制御パターンに対して\n        for j in range(2 ** k):\n            base = j * step\n            # denominator = sum_{l=0}^{step-1} |psi_big[base+l]|^2\n            denom = 0.0\n            for l in range(step):\n                denom += psi_big[base + l] ** 2\n            if abs(denom) < 1e-12:\n                continue  # このブロックはゼロベクトルなのでスキップ\n            num = 0.0\n            for l in range(half):\n                num += psi_big[base + l] ** 2\n            ratio = num / denom\n            # 浮動小数点誤差対策：ratio ∈ [0,1]に\n            ratio = min(max(ratio, 0.0), 1.0)\n            theta = 2 * math.acos(math.sqrt(ratio))\n            if abs(theta) < 1e-12:\n                continue  # 回転角がほぼ 0 なら省略\n\n            target = n - k - 1  # この段の対象ワイヤ\n            if k == 0:\n                # 制御ビットがない場合は通常の Ry\n                qc.ry(theta, target)\n            else:\n                # 制御ビットは，これまでに処理済みの上位ワイヤ（big–endian順）\n                # ここでは，制御ワイヤは [n-1, n-2, …, n-k]（降順）とする．\n                control_qubits = list(range(n - k, n))\n                # 制御パターンは，j を k–bit の 2進数で表したもの\n                bin_str = format(j, '0{}b'.format(k))\n                # もし対応するビットが '0' なら X–ゲートで反転（前後に挿入）\n                for idx, bit in zip(control_qubits, bin_str):\n                    if bit == '0':\n                        qc.x(idx)\n                # 多重制御付き Ry（ancilla なしモード）\n                qc.mcry(theta, control_qubits, target, None, mode='noancilla')\n                for idx, bit in zip(control_qubits, bin_str):\n                    if bit == '0':\n                        qc.x(idx)\n                        \n    # ここまでの手続きで，psi_big を作る回路ができあがっている．\n    # しかし，psi_big で作られた状態は回路中では big–endian表記となっているので，\n    # 最後にワイヤの順番を反転する（SWAP）ことで little–endian に合わせる．\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AEB7ECC5D922C", "submission_order": 1, "result": "WA", "execution_time": "959 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    # 引く\n    # L2 = (1 << n) - L\n    # print(\"L2 = \", L2)    \n    # for i in range(n):\n    #     if L2 & (1 << (n - i - 1)) != 0:\n    #         print(\"i = \", i)\n    #         controls = []\n    #         for k in range(i):\n    #             controls.append(n-1-k)\n    #         if len(controls) > 0:\n    #             qc.mcp(math.pi, controls, n-1-i)\n    #         else:\n    #             qc.z(n-1-i)\n    #         qc.x(n-1-i)\n    # for i in reversed(range(n)):\n    #     if L2 & (1 << (n - i - 1)) != 0:\n    #         qc.x(n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AEB7ECC5D922C", "submission_order": 2, "result": "WA", "execution_time": "1024 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    rem = L\n    controls = []\n    for i in reversed(range(n)):\n        if rem >= 1 << i:\n            n0 = 1 << i\n            n1 = rem - n0\n            print(f\"i = {i}, {rem} -> {n0}, {n1}\")\n            r0 = math.acos(math.sqrt(n0/(n0+n1)))*2.0\n            r1 = math.acos(math.sqrt(n1/(n0+n1)))*2.0\n            if len(controls) > 0:\n                for k in controls:\n                    qc.x(k)\n\n                qc.mcry(r0, controls, i)\n\n                qc.x(i)\n                controls.append(i)\n                for k in range(i):\n                    qc.ry(math.pi / 4.0, k)\n                    qc.mcrz(math.pi, controls, k)\n                    qc.ry(-math.pi / 4.0, k)\n                controls = controls[:-1]\n                qc.x(i)\n\n                for k in controls:\n                    qc.x(k)\n            else:\n                qc.ry(r1, i)\n\n            \n\n            rem = n1\n\n        controls.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AEB7ECC5D922C", "submission_order": 3, "result": "WA", "execution_time": "1223 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    rem = L\n    controls = []\n    for i in reversed(range(n)):\n        if rem >= 1 << i:\n            n0 = 1 << i\n            n1 = rem - n0\n            print(f\"i = {i}, {rem} -> {n0}, {n1}\")\n            r0 = math.acos(math.sqrt(n0/(n0+n1)))*2.0\n            r1 = math.acos(math.sqrt(n1/(n0+n1)))*2.0\n            if len(controls) > 0:\n                for k in controls:\n                    qc.x(k)\n\n                qc.mcry(r0, controls, i)\n\n                qc.x(i)\n                controls.append(i)\n                for k in range(i):\n                    qc.ry(math.pi / 4.0, k)\n                    # qc.mcrz(math.pi, controls, k)\n                    qc.ry(-math.pi / 4.0, k)\n                controls = controls[:-1]\n                qc.x(i)\n\n                for k in controls:\n                    qc.x(k)\n            else:\n                qc.ry(r1, i)\n\n            \n\n            rem = n1\n\n        controls.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AEB7ECC5D922C", "submission_order": 4, "result": "WA", "execution_time": "1041 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    rem = L\n    controls = []\n    for i in reversed(range(n)):\n        if rem >= 1 << i:\n            n0 = 1 << i\n            n1 = rem - n0\n            print(f\"i = {i}, {rem} -> {n0}, {n1}\")\n            r0 = math.acos(math.sqrt(n0/(n0+n1)))*2.0\n            r1 = math.acos(math.sqrt(n1/(n0+n1)))*2.0\n            if len(controls) > 0:\n                for k in controls:\n                    qc.x(k)\n\n                # qc.mcry(r0, controls, i)\n\n                qc.x(i)\n                controls.append(i)\n                for k in range(i):\n                    qc.ry(math.pi / 4.0, k)\n                    # qc.mcrz(math.pi, controls, k)\n                    qc.ry(-math.pi / 4.0, k)\n                controls = controls[:-1]\n                qc.x(i)\n\n                for k in controls:\n                    qc.x(k)\n            else:\n                qc.ry(r1, i)\n\n            \n\n            rem = n1\n\n        controls.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AEB7ECC5D922C", "submission_order": 5, "result": "WA", "execution_time": "949 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    rem = L\n    controls = []\n    for i in reversed(range(n)):\n        if rem >= 1 << i:\n            n0 = 1 << i\n            n1 = rem - n0\n            print(f\"i = {i}, {rem} -> {n0}, {n1}\")\n            r0 = math.acos(math.sqrt(n0/(n0+n1)))*2.0\n            r1 = math.acos(math.sqrt(n1/(n0+n1)))*2.0\n            if len(controls) > 0:\n                for k in controls:\n                    qc.x(k)\n\n                #qc.mcry(r0, controls, i)\n\n                qc.x(i)\n                controls.append(i)\n                for k in range(i):\n                    qc.ry(math.pi / 4.0, k)\n                    qc.mcrz(math.pi, controls, k)\n                    qc.ry(-math.pi / 4.0, k)\n                controls = controls[:-1]\n                qc.x(i)\n\n                for k in controls:\n                    qc.x(k)\n            else:\n                qc.ry(r1, i)\n\n            \n\n            rem = n1\n\n        controls.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AEB7ECC5D922C", "submission_order": 6, "result": "WA", "execution_time": "1259 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    rem = L\n    controls = []\n    for i in reversed(range(n)):\n        if rem >= 1 << i:\n            n0 = 1 << i\n            n1 = rem - n0\n            print(f\"i = {i}, {rem} -> {n0}, {n1}\")\n            r0 = math.acos(math.sqrt(n0/(n0+n1)))*2.0\n            r1 = math.acos(math.sqrt(n1/(n0+n1)))*2.0\n            if len(controls) > 0:\n                for k in controls:\n                    qc.x(k)\n\n                qc.mcry(r0, controls, i)\n\n                qc.x(i)\n                controls.append(i)\n                for k in range(i):\n                    qc.ry(math.pi / 4.0, k)\n                    qc.mcp(math.pi, controls, k)\n                    qc.ry(-math.pi / 4.0, k)\n                controls = controls[:-1]\n                qc.x(i)\n\n                for k in controls:\n                    qc.x(k)\n            else:\n                qc.ry(r1, i)\n\n            \n\n            rem = n1\n\n        controls.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AEB7ECC5D922C", "submission_order": 7, "result": "WA", "execution_time": "995 ms", "memory": "91 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    rem = L\n    controls = []\n    for i in reversed(range(n)):\n        if rem >= 1 << i:\n            n0 = 1 << i\n            n1 = rem - n0\n            print(f\"i = {i}, {rem} -> {n0}, {n1}\")\n            r0 = math.acos(math.sqrt(n0/(n0+n1)))*2.0\n            r1 = math.acos(math.sqrt(n1/(n0+n1)))*2.0\n            if len(controls) > 0:\n                for k in controls:\n                    qc.x(k)\n\n                qc.mcry(r0, controls, i)\n\n                qc.x(i)\n                controls.append(i)\n                for k in range(i):\n                    qc.ry(-math.pi / 4.0, k)\n                    qc.mcp(math.pi, controls, k)\n                    qc.ry(math.pi / 4.0, k)\n                controls = controls[:-1]\n                qc.x(i)\n\n                for k in controls:\n                    qc.x(k)\n            else:\n                qc.ry(r1, i)\n\n            \n\n            rem = n1\n\n        controls.append(i)\n\n    return qc\n'''"}
{"problem": "QPC001_C2", "user": "AEB7ECC5D922C", "submission_order": 8, "result": "WA", "execution_time": "987 ms", "memory": "90 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # グローバル位相は無視して良いので、全部ひっくり返す場合は何もしない\n    if L == 1 << n:\n        for i in range(n):\n            qc.h(i)\n        return qc\n    rem = L\n    controls = []\n    for i in reversed(range(n)):\n        if rem >= 1 << i:\n            n0 = 1 << i\n            n1 = rem - n0\n            print(f\"i = {i}, {rem} -> {n0}, {n1}\")\n            r0 = math.acos(math.sqrt(n0/(n0+n1)))*2.0\n            r1 = math.acos(math.sqrt(n1/(n0+n1)))*2.0\n            if len(controls) > 0:\n                for k in controls:\n                    qc.x(k)\n\n                # qc.mcry(r0, controls, i)\n                qc.ry(r0, i)\n\n                qc.x(i)\n                controls.append(i)\n                for k in range(i):\n                    print(f\"k = {k}\")\n                    qc.ry(math.pi / 4.0, k)\n                    qc.mcp(math.pi, controls, k)\n                    qc.ry(-math.pi / 4.0, k)\n                controls = controls[:-1]\n                qc.x(i)\n\n                for k in controls:\n                    qc.x(k)\n            else:\n                qc.ry(r1, i)\n\n            \n\n            rem = n1\n\n        controls.append(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0088922EB389", "submission_order": 1, "result": "WA", "execution_time": "1997 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(3.14159, 0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0088922EB389", "submission_order": 2, "result": "RE", "execution_time": "1474 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.i(0)  # Identit operation to maintain |0⟩ state\n    qc.z(0)     # Wrte your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0088922EB389", "submission_order": 3, "result": "RE", "execution_time": "1133 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(np.pi/2, 0)\n# Wrte your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0088922EB389", "submission_order": 4, "result": "WA", "execution_time": "1606 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.z(0)\n# Wrte your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A02D4975E26AC", "submission_order": 1, "result": "AC", "execution_time": "1596 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0314B43EA985", "submission_order": 1, "result": "WA", "execution_time": "1440 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0314B43EA985", "submission_order": 2, "result": "WA", "execution_time": "1196 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(np.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0314B43EA985", "submission_order": 3, "result": "WA", "execution_time": "1105 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0314B43EA985", "submission_order": 4, "result": "AC", "execution_time": "1447 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0638B5F1FE8E", "submission_order": 1, "result": "AC", "execution_time": "1436 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A06A20112A437", "submission_order": 1, "result": "AC", "execution_time": "1418 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A06A23ED1FB09", "submission_order": 1, "result": "AC", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0859F6BEEFE8", "submission_order": 1, "result": "AC", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A08BCA6C8470F", "submission_order": 1, "result": "RE", "execution_time": "1377 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.g(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A08BCA6C8470F", "submission_order": 2, "result": "WA", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A08BCA6C8470F", "submission_order": 3, "result": "WA", "execution_time": "1383 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A08BCA6C8470F", "submission_order": 4, "result": "RE", "execution_time": "1452 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A08BCA6C8470F", "submission_order": 5, "result": "WA", "execution_time": "1490 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A08BCA6C8470F", "submission_order": 6, "result": "WA", "execution_time": "1365 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A08BCA6C8470F", "submission_order": 7, "result": "WA", "execution_time": "1398 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.s(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A08BCA6C8470F", "submission_order": 8, "result": "AC", "execution_time": "1558 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0997082DAD11", "submission_order": 1, "result": "RE", "execution_time": "1495 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0997082DAD11", "submission_order": 2, "result": "RE", "execution_time": "1332 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0997082DAD11", "submission_order": 3, "result": "WA", "execution_time": "1403 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0997082DAD11", "submission_order": 4, "result": "AC", "execution_time": "1481 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0ABA2D9E64BD", "submission_order": 1, "result": "WA", "execution_time": "1600 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.y(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0ABA2D9E64BD", "submission_order": 2, "result": "AC", "execution_time": "1344 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n    qc.h(0)\n    qc.x(0)\n    qc.h(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0CBC047ECE2C", "submission_order": 1, "result": "AC", "execution_time": "1401 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0D133F34F2F8", "submission_order": 1, "result": "WA", "execution_time": "1372 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0D133F34F2F8", "submission_order": 2, "result": "AC", "execution_time": "1095 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0E9C48D93C6C", "submission_order": 1, "result": "RE", "execution_time": "1269 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qz.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0E9C48D93C6C", "submission_order": 2, "result": "AC", "execution_time": "1413 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0ED03DB80E91", "submission_order": 1, "result": "WA", "execution_time": "1505 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0ED03DB80E91", "submission_order": 2, "result": "AC", "execution_time": "1019 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.x(0)\n    qc.h(0)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0EFBED772E8C", "submission_order": 1, "result": "AC", "execution_time": "1099 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A0FF8F4C15B7C", "submission_order": 1, "result": "AC", "execution_time": "1544 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A103B161D8729", "submission_order": 1, "result": "AC", "execution_time": "1249 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A105FB564F144", "submission_order": 1, "result": "AC", "execution_time": "1140 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A10B7C9112EBF", "submission_order": 1, "result": "WA", "execution_time": "1406 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A10B7C9112EBF", "submission_order": 2, "result": "WA", "execution_time": "1392 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(3.14159, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A10B7C9112EBF", "submission_order": 3, "result": "RE", "execution_time": "1503 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A10B7C9112EBF", "submission_order": 4, "result": "AC", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1101865F6163", "submission_order": 1, "result": "AC", "execution_time": "1344 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A11921B3F8535", "submission_order": 1, "result": "WA", "execution_time": "1337 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A11921B3F8535", "submission_order": 2, "result": "WA", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A11921B3F8535", "submission_order": 3, "result": "AC", "execution_time": "1191 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A11C133ED80AA", "submission_order": 1, "result": "RE", "execution_time": "1694 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A11C133ED80AA", "submission_order": 2, "result": "AC", "execution_time": "1386 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A12A661B288C0", "submission_order": 1, "result": "RE", "execution_time": "1273 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta = 4 * math.atan(0/-1) \n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A12A661B288C0", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta = 4 * math.atan(0/-) \n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A12A661B288C0", "submission_order": 3, "result": "WA", "execution_time": "1379 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta = math.atan(0/-1) \n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A12A661B288C0", "submission_order": 4, "result": "WA", "execution_time": "1387 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta = math.atan(math.pi) \n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A12A661B288C0", "submission_order": 5, "result": "WA", "execution_time": "1082 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta = math.atan(2*math.pi) \n    qc.rx(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A12A661B288C0", "submission_order": 6, "result": "AC", "execution_time": "1219 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta = 2*math.pi\n    qc.rx(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A12C8907BD3FC", "submission_order": 1, "result": "AC", "execution_time": "1219 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A12C8907BD3FC", "submission_order": 2, "result": "AC", "execution_time": "1219 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1351241D0120", "submission_order": 1, "result": "AC", "execution_time": "1408 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A136BE97F55A5", "submission_order": 1, "result": "AC", "execution_time": "2088 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A146F9E67A67C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport math\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library.standard_gates import (\n    C3XGate,\n    C3SXGate,\n    C4XGate,\n    CCXGate,\n    DCXGate,\n    CHGate,\n    CPhaseGate,\n    CRXGate,\n    CRYGate,\n    CRZGate,\n    CSwapGate,\n    CSXGate,\n    CUGate,\n    CU1Gate,\n    CU3Gate,\n    CXGate,\n    CYGate,\n    CZGate,\n    CCZGate,\n    HGate,\n    IGate,\n    MCPhaseGate,\n    PhaseGate,\n    RCCXGate,\n    RC3XGate,\n    RXGate,\n    RXXGate,\n    RYGate,\n    RYYGate,\n    RZGate,\n    RZZGate,\n    RZXGate,\n    XXMinusYYGate,\n    XXPlusYYGate,\n    ECRGate,\n    SGate,\n    SdgGate,\n    CSGate,\n    CSdgGate,\n    SwapGate,\n    iSwapGate,\n    SXGate,\n    SXdgGate,\n    TGate,\n    TdgGate,\n    UGate,\n    U1Gate,\n    U2Gate,\n    U3Gate,\n    XGate,\n    YGate,\n    ZGate,\n)\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC002_A1", "user": "A146F9E67A67C", "submission_order": 2, "result": "AC", "execution_time": "1366 ms", "memory": "155 MiB", "code": "'''python\nimport math\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import (\n    C3XGate,\n    C3SXGate,\n    C4XGate,\n    CCXGate,\n    DCXGate,\n    CHGate,\n    CPhaseGate,\n    CRXGate,\n    CRYGate,\n    CRZGate,\n    CSwapGate,\n    CSXGate,\n    CUGate,\n    CU1Gate,\n    CU3Gate,\n    CXGate,\n    CYGate,\n    CZGate,\n    CCZGate,\n    HGate,\n    IGate,\n    MCPhaseGate,\n    PhaseGate,\n    RCCXGate,\n    RC3XGate,\n    RXGate,\n    RXXGate,\n    RYGate,\n    RYYGate,\n    RZGate,\n    RZZGate,\n    RZXGate,\n    XXMinusYYGate,\n    XXPlusYYGate,\n    ECRGate,\n    SGate,\n    SdgGate,\n    CSGate,\n    CSdgGate,\n    SwapGate,\n    iSwapGate,\n    SXGate,\n    SXdgGate,\n    TGate,\n    TdgGate,\n    UGate,\n    U1Gate,\n    U2Gate,\n    U3Gate,\n    XGate,\n    YGate,\n    ZGate,\n)\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A148ACD0A713C", "submission_order": 1, "result": "AC", "execution_time": "1252 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A16733186A614", "submission_order": 1, "result": "RE", "execution_time": "1399 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x()\n    qc.z()\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A16733186A614", "submission_order": 2, "result": "AC", "execution_time": "1429 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A180B70C77B41", "submission_order": 1, "result": "WA", "execution_time": "1361 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A180B70C77B41", "submission_order": 2, "result": "AC", "execution_time": "1368 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1A95116F1DF7", "submission_order": 1, "result": "AC", "execution_time": "1163 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1AD51F07C67C", "submission_order": 1, "result": "AC", "execution_time": "1653 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1CF476F376D3", "submission_order": 1, "result": "AC", "execution_time": "1914 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D420AA8B839", "submission_order": 1, "result": "WA", "execution_time": "1400 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D420AA8B839", "submission_order": 2, "result": "WA", "execution_time": "1385 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D420AA8B839", "submission_order": 3, "result": "WA", "execution_time": "1420 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.id(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D420AA8B839", "submission_order": 4, "result": "WA", "execution_time": "1408 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.id(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D420AA8B839", "submission_order": 5, "result": "AC", "execution_time": "1347 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D6F666C3A4C", "submission_order": 1, "result": "WA", "execution_time": "1750 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(pi,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D6F666C3A4C", "submission_order": 2, "result": "RE", "execution_time": "2000 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(pi,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D6F666C3A4C", "submission_order": 3, "result": "RE", "execution_time": "1447 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    # Write your code here:\n    qc.p(pi)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D6F666C3A4C", "submission_order": 4, "result": "WA", "execution_time": "1366 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # create -|0> state\n    qc.x(0)\n    qc.h(0)\n    qc.rz(pi/4, 0)\n    qc.h(0)\n  \n\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1D6F666C3A4C", "submission_order": 5, "result": "AC", "execution_time": "1467 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A1E9067C78BBC", "submission_order": 1, "result": "AC", "execution_time": "1361 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A205418F377CF", "submission_order": 1, "result": "AC", "execution_time": "1358 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A22690DCDA3D5", "submission_order": 1, "result": "AC", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A25F5CE9D6317", "submission_order": 1, "result": "WA", "execution_time": "1533 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A25F5CE9D6317", "submission_order": 2, "result": "WA", "execution_time": "1473 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A25F5CE9D6317", "submission_order": 3, "result": "WA", "execution_time": "1177 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A25F5CE9D6317", "submission_order": 4, "result": "WA", "execution_time": "1430 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A25F5CE9D6317", "submission_order": 5, "result": "WA", "execution_time": "1433 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A25F5CE9D6317", "submission_order": 6, "result": "RE", "execution_time": "1252 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.cx(0, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A25F5CE9D6317", "submission_order": 7, "result": "RE", "execution_time": "1101 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.cx(0, 0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A25F5CE9D6317", "submission_order": 8, "result": "AC", "execution_time": "1371 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 1, "result": "WA", "execution_time": "1383 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.s(0)  # Apply the S gate (phase of π/2)\n    qc.z(0)  # Apply the Z gate (phase of π)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 2, "result": "WA", "execution_time": "1388 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(-3.14159, 0)  # Apply a phase of -π to the qubit\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 3, "result": "WA", "execution_time": "1232 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.p(-3.14159, 0)  # Apply a phase shift of -π to the qubit\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 4, "result": "WA", "execution_time": "1060 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0) \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 5, "result": "WA", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.s(0)  # Apply the S-gate\n    qc.z(0) \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 6, "result": "WA", "execution_time": "1346 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)  # Create a quantum circuit with 1 qubit\n    qc.z(0)  # Apply the Z gate to the qubit to add a phase of π\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 7, "result": "WA", "execution_time": "1653 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.p(pi, 0)  # Apply a phase gate with phase pi\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 8, "result": "WA", "execution_time": "1476 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 9, "result": "RE", "execution_time": "1102 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(PhaseGate(pi), [0])\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 10, "result": "RE", "execution_time": "1334 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    # Apply the phase shift gate with phase π to introduce a global phase of -1\n    qc.p(pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 11, "result": "WA", "execution_time": "1460 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    # Apply the phase shift gate with phase π to introduce a global phase of -1\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 12, "result": "WA", "execution_time": "1820 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    # Apply the phase shift gate with phase π to introduce a global phase of -1\n    qc.x(0)  # Apply X gate to the qubit\n    qc.z(0)  # Apply Z gate to the qubit\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 13, "result": "RE", "execution_time": "1472 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    # Apply the phase shift gate with phase π to introduce a global phase of -1\n\n    qc.rz(pi, 0) \n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 14, "result": "WA", "execution_time": "1475 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    # Apply the phase shift gate with phase π to introduce a global phase of -1\n\n    qc.z(0) \n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A29B4B9758C17", "submission_order": 15, "result": "AC", "execution_time": "1430 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A2A2A1EA625EB", "submission_order": 1, "result": "WA", "execution_time": "1560 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A2A2A1EA625EB", "submission_order": 2, "result": "WA", "execution_time": "1437 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(2*pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A2A2A1EA625EB", "submission_order": 3, "result": "AC", "execution_time": "1497 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A2F2C448CC4F7", "submission_order": 1, "result": "RE", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.Z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A2F2C448CC4F7", "submission_order": 2, "result": "WA", "execution_time": "1346 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A2F2C448CC4F7", "submission_order": 3, "result": "AC", "execution_time": "1465 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A300FE7ED6B38", "submission_order": 1, "result": "AC", "execution_time": "1376 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A308890559BAC", "submission_order": 1, "result": "AC", "execution_time": "1360 ms", "memory": "155 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A32A94D4EFD7C", "submission_order": 1, "result": "AC", "execution_time": "1331 ms", "memory": "140 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(2 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A337AC85DCDE9", "submission_order": 1, "result": "AC", "execution_time": "1641 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A343D583840FE", "submission_order": 1, "result": "AC", "execution_time": "1405 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A344CCD1801E4", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n \n \n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A1", "user": "A344CCD1801E4", "submission_order": 2, "result": "AC", "execution_time": "2032 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n \n \n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A1", "user": "A37D3A5E23951", "submission_order": 1, "result": "AC", "execution_time": "1483 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39D898DD7602", "submission_order": 1, "result": "AC", "execution_time": "1094 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39EF4D7AA86C", "submission_order": 1, "result": "RE", "execution_time": "1299 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39EF4D7AA86C", "submission_order": 2, "result": "WA", "execution_time": "1061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39EF4D7AA86C", "submission_order": 3, "result": "WA", "execution_time": "1441 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39EF4D7AA86C", "submission_order": 4, "result": "RE", "execution_time": "1074 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39EF4D7AA86C", "submission_order": 5, "result": "WA", "execution_time": "1362 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39EF4D7AA86C", "submission_order": 6, "result": "WA", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39EF4D7AA86C", "submission_order": 7, "result": "WA", "execution_time": "1349 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A39EF4D7AA86C", "submission_order": 8, "result": "WA", "execution_time": "1165 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3B50D8CE4419", "submission_order": 1, "result": "AC", "execution_time": "1353 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3B537940B8BA", "submission_order": 1, "result": "WA", "execution_time": "1437 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3B537940B8BA", "submission_order": 2, "result": "WA", "execution_time": "1459 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3B537940B8BA", "submission_order": 3, "result": "AC", "execution_time": "1413 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3F586EC178B5", "submission_order": 1, "result": "WA", "execution_time": "1119 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3F586EC178B5", "submission_order": 2, "result": "WA", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3F586EC178B5", "submission_order": 3, "result": "RE", "execution_time": "1135 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(3 * np.pi / 2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3F586EC178B5", "submission_order": 4, "result": "WA", "execution_time": "1488 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(3 * np.pi / 2,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3F586EC178B5", "submission_order": 5, "result": "RE", "execution_time": "1369 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3F586EC178B5", "submission_order": 6, "result": "WA", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi ,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A3F586EC178B5", "submission_order": 7, "result": "AC", "execution_time": "1474 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * np.pi ,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A40E67A6AC2D1", "submission_order": 1, "result": "RE", "execution_time": "1118 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A40E67A6AC2D1", "submission_order": 2, "result": "AC", "execution_time": "1545 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A41B2FF86B8FE", "submission_order": 1, "result": "WA", "execution_time": "1552 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A41B2FF86B8FE", "submission_order": 2, "result": "AC", "execution_time": "1550 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A435762EBC103", "submission_order": 1, "result": "WA", "execution_time": "1490 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A435762EBC103", "submission_order": 2, "result": "AC", "execution_time": "1436 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A43979E650932", "submission_order": 1, "result": "AC", "execution_time": "1623 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A458F4F43A4A0", "submission_order": 1, "result": "AC", "execution_time": "1208 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A4619843044B8", "submission_order": 1, "result": "AC", "execution_time": "1136 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.x(0)\n    qc.h(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A4D7CC9628563", "submission_order": 1, "result": "RE", "execution_time": "1208 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi*2)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A4D7CC9628563", "submission_order": 2, "result": "AC", "execution_time": "1132 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi*2,0)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A4E505298ABC0", "submission_order": 1, "result": "AC", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A4ED5590CD5A0", "submission_order": 1, "result": "RE", "execution_time": "1099 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n\nret = solve()\nret.draw(\"mpl\")\n'''"}
{"problem": "QPC002_A1", "user": "A4ED5590CD5A0", "submission_order": 2, "result": "AC", "execution_time": "1372 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A51D06BBA4300", "submission_order": 1, "result": "RE", "execution_time": "1408 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A51D06BBA4300", "submission_order": 2, "result": "WA", "execution_time": "1152 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A51D06BBA4300", "submission_order": 3, "result": "WA", "execution_time": "1390 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A51D06BBA4300", "submission_order": 4, "result": "WA", "execution_time": "1726 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.reset(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A51D06BBA4300", "submission_order": 5, "result": "WA", "execution_time": "1140 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A51D06BBA4300", "submission_order": 6, "result": "WA", "execution_time": "1451 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A51D06BBA4300", "submission_order": 7, "result": "AC", "execution_time": "1110 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5224CD102DDE", "submission_order": 1, "result": "AC", "execution_time": "1916 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n \n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A52B6A3D34137", "submission_order": 1, "result": "WA", "execution_time": "1369 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A52B6A3D34137", "submission_order": 2, "result": "AC", "execution_time": "1084 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A552165C560AC", "submission_order": 1, "result": "AC", "execution_time": "1361 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A572EA2332518", "submission_order": 1, "result": "WA", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A572EA2332518", "submission_order": 2, "result": "WA", "execution_time": "1447 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A572EA2332518", "submission_order": 3, "result": "AC", "execution_time": "1892 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A57C8CD5D056F", "submission_order": 1, "result": "AC", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A58376EB31FE4", "submission_order": 1, "result": "AC", "execution_time": "1415 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 1, "result": "WA", "execution_time": "1447 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 2, "result": "WA", "execution_time": "1167 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 3, "result": "RE", "execution_time": "1491 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 4, "result": "RE", "execution_time": "1049 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(0)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 5, "result": "RE", "execution_time": "1456 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(ZGate(), [1])\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 6, "result": "WA", "execution_time": "1451 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(ZGate(), [0])\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 7, "result": "WA", "execution_time": "1737 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(ZGate(), [0])\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 8, "result": "WA", "execution_time": "1431 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 9, "result": "RE", "execution_time": "1442 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 10, "result": "WA", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 11, "result": "RE", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z()\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 12, "result": "RE", "execution_time": "1425 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 13, "result": "WA", "execution_time": "1057 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 14, "result": "WA", "execution_time": "1363 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 15, "result": "WA", "execution_time": "1415 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 16, "result": "WA", "execution_time": "1424 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 17, "result": "WA", "execution_time": "1422 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 18, "result": "WA", "execution_time": "1373 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5C8768C72E74", "submission_order": 19, "result": "WA", "execution_time": "1154 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.sdg(0)\n    qc.sdg(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5EAE82CD9CC1", "submission_order": 1, "result": "AC", "execution_time": "1935 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A5FF5F7AAADF3", "submission_order": 1, "result": "AC", "execution_time": "1369 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A610C1921B5AF", "submission_order": 1, "result": "WA", "execution_time": "1058 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # Apply the Z gate to the qubit to create the state -|0>\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 1, "result": "WA", "execution_time": "1024 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 2, "result": "RE", "execution_time": "1060 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 3, "result": "WA", "execution_time": "1042 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 4, "result": "RE", "execution_time": "1409 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 5, "result": "WA", "execution_time": "1412 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 6, "result": "WA", "execution_time": "1480 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 7, "result": "WA", "execution_time": "1429 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 8, "result": "WA", "execution_time": "1130 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 9, "result": "WA", "execution_time": "1044 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 10, "result": "RE", "execution_time": "1418 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 11, "result": "RE", "execution_time": "1473 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 12, "result": "WA", "execution_time": "1557 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 13, "result": "WA", "execution_time": "1229 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 14, "result": "WA", "execution_time": "1457 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 15, "result": "RE", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 16, "result": "WA", "execution_time": "1438 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    return qc\n    \nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 17, "result": "WA", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 18, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 19, "result": "WA", "execution_time": "1440 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 20, "result": "RE", "execution_time": "1707 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 21, "result": "RE", "execution_time": "1443 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(1,0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 22, "result": "WA", "execution_time": "1124 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 23, "result": "WA", "execution_time": "1892 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 24, "result": "WA", "execution_time": "1130 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 25, "result": "WA", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 26, "result": "WA", "execution_time": "1130 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 27, "result": "WA", "execution_time": "1678 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 28, "result": "RE", "execution_time": "1094 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.z(0)\n    \n    return qc\n\nqc = solve()\nqc.draw('mpl')\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 29, "result": "RE", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.cx(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 30, "result": "WA", "execution_time": "1339 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A633E067364EA", "submission_order": 31, "result": "WA", "execution_time": "1559 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 1, "result": "RE", "execution_time": "1367 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 2, "result": "RE", "execution_time": "1362 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    x(qc)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 3, "result": "WA", "execution_time": "1160 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 4, "result": "WA", "execution_time": "1361 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 5, "result": "RE", "execution_time": "1043 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.cx(0, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 6, "result": "RE", "execution_time": "1164 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qiskit.x(qc)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 7, "result": "WA", "execution_time": "1125 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 8, "result": "WA", "execution_time": "1335 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 9, "result": "WA", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 10, "result": "WA", "execution_time": "1439 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.reset(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 11, "result": "RE", "execution_time": "1486 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc * -1\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 12, "result": "RE", "execution_time": "1473 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 13, "result": "WA", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 14, "result": "WA", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 15, "result": "WA", "execution_time": "1581 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 16, "result": "RE", "execution_time": "1550 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 17, "result": "WA", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(pi,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 18, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p（）\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 19, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p（0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 20, "result": "WA", "execution_time": "1316 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 21, "result": "WA", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A680DEE7BD42B", "submission_order": 22, "result": "AC", "execution_time": "1366 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A68359E63DB99", "submission_order": 1, "result": "AC", "execution_time": "1865 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A6C6E7C8B922D", "submission_order": 1, "result": "AC", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A6F4591DA3629", "submission_order": 1, "result": "AC", "execution_time": "1725 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A7006DED61EC1", "submission_order": 1, "result": "AC", "execution_time": "1097 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A70312C27F6D7", "submission_order": 1, "result": "WA", "execution_time": "1385 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A70312C27F6D7", "submission_order": 2, "result": "WA", "execution_time": "1214 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A70312C27F6D7", "submission_order": 3, "result": "WA", "execution_time": "1382 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A70312C27F6D7", "submission_order": 4, "result": "AC", "execution_time": "1138 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:+\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A70B4E75040E4", "submission_order": 1, "result": "WA", "execution_time": "1844 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A70B4E75040E4", "submission_order": 2, "result": "AC", "execution_time": "1480 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A733977EFFCF8", "submission_order": 1, "result": "AC", "execution_time": "1112 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A767884C7DD9C", "submission_order": 1, "result": "AC", "execution_time": "1170 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A77B3D0CA6400", "submission_order": 1, "result": "WA", "execution_time": "1973 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A77B3D0CA6400", "submission_order": 2, "result": "WA", "execution_time": "1955 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A77B3D0CA6400", "submission_order": 3, "result": "AC", "execution_time": "2068 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A78033229272B", "submission_order": 1, "result": "WA", "execution_time": "1411 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A78033229272B", "submission_order": 2, "result": "AC", "execution_time": "1481 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A785B603D1E48", "submission_order": 1, "result": "RE", "execution_time": "1373 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    -qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A785B603D1E48", "submission_order": 2, "result": "WA", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A785B603D1E48", "submission_order": 3, "result": "WA", "execution_time": "1189 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A79646CB29FA3", "submission_order": 1, "result": "AC", "execution_time": "1418 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A798410E3BD76", "submission_order": 1, "result": "AC", "execution_time": "1582 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A7D7428A222F0", "submission_order": 1, "result": "AC", "execution_time": "1215 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A7E914CD0774C", "submission_order": 1, "result": "AC", "execution_time": "1103 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)    \n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A83D30D6FEE38", "submission_order": 1, "result": "AC", "execution_time": "1610 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A83DB0768311B", "submission_order": 1, "result": "AC", "execution_time": "1468 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 1, "result": "WA", "execution_time": "1144 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 2, "result": "WA", "execution_time": "1195 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 3, "result": "WA", "execution_time": "1129 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 4, "result": "WA", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 5, "result": "WA", "execution_time": "1387 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 6, "result": "WA", "execution_time": "1362 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 7, "result": "WA", "execution_time": "1578 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 8, "result": "WA", "execution_time": "1787 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A84CD5EFBB91B", "submission_order": 9, "result": "AC", "execution_time": "1349 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A85B223358AA8", "submission_order": 1, "result": "AC", "execution_time": "1158 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A885EFC643938", "submission_order": 1, "result": "AC", "execution_time": "1433 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A88F9E13BF35D", "submission_order": 1, "result": "AC", "execution_time": "1799 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8AEBF28FE4F5", "submission_order": 1, "result": "AC", "execution_time": "1978 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8B8B138D0C54", "submission_order": 1, "result": "WA", "execution_time": "1470 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8B8B138D0C54", "submission_order": 2, "result": "RE", "execution_time": "1481 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.zdg(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8B8B138D0C54", "submission_order": 3, "result": "AC", "execution_time": "1454 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8C4F44A63418", "submission_order": 1, "result": "AC", "execution_time": "1470 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import GlobalPhaseGate\nimport math\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(1)\n  qc.append(GlobalPhaseGate(math.pi))\n  return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8C59A1DDA2EA", "submission_order": 1, "result": "WA", "execution_time": "1399 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8C59A1DDA2EA", "submission_order": 2, "result": "WA", "execution_time": "1385 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8C59A1DDA2EA", "submission_order": 3, "result": "RE", "execution_time": "1388 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8C59A1DDA2EA", "submission_order": 4, "result": "RE", "execution_time": "1381 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(\n    HGate(),  # New HGate instruction\n    [0]       # Apply to qubit 0\n)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8C59A1DDA2EA", "submission_order": 5, "result": "WA", "execution_time": "1393 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.sdg(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8C59A1DDA2EA", "submission_order": 6, "result": "AC", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.global_phase = 3.14159\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8D033E80A791", "submission_order": 1, "result": "WA", "execution_time": "1169 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8D033E80A791", "submission_order": 2, "result": "AC", "execution_time": "1133 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8DBFEC28A0A5", "submission_order": 1, "result": "WA", "execution_time": "1192 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8DBFEC28A0A5", "submission_order": 2, "result": "WA", "execution_time": "1139 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8DBFEC28A0A5", "submission_order": 3, "result": "WA", "execution_time": "1340 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8DBFEC28A0A5", "submission_order": 4, "result": "WA", "execution_time": "1400 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.rz(math.pi,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8DBFEC28A0A5", "submission_order": 5, "result": "WA", "execution_time": "1454 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.rz(math.pi,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8DBFEC28A0A5", "submission_order": 6, "result": "WA", "execution_time": "1402 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(math.pi,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8DBFEC28A0A5", "submission_order": 7, "result": "AC", "execution_time": "1192 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rx(2*math.pi,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A8EC1B8D518A3", "submission_order": 1, "result": "WA", "execution_time": "1430 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9069EE151EBA", "submission_order": 1, "result": "RE", "execution_time": "1460 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.draw(output='mpl')\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9069EE151EBA", "submission_order": 2, "result": "RE", "execution_time": "1412 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\nqc=solve()\nqc.draw(output='mpl')\n'''"}
{"problem": "QPC002_A1", "user": "A9069EE151EBA", "submission_order": 3, "result": "WA", "execution_time": "1407 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\nqc=solve()\n'''"}
{"problem": "QPC002_A1", "user": "A919A921A312C", "submission_order": 1, "result": "AC", "execution_time": "1824 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9628FFD02887", "submission_order": 1, "result": "AC", "execution_time": "1241 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 1, "result": "RE", "execution_time": "1059 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 2, "result": "WA", "execution_time": "1617 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 3, "result": "WA", "execution_time": "1407 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 4, "result": "WA", "execution_time": "1419 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 5, "result": "WA", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 6, "result": "RE", "execution_time": "1174 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 7, "result": "WA", "execution_time": "1786 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 8, "result": "WA", "execution_time": "1347 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 9, "result": "WA", "execution_time": "1382 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 10, "result": "WA", "execution_time": "1830 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 11, "result": "RE", "execution_time": "1379 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 12, "result": "WA", "execution_time": "1853 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(np.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 13, "result": "RE", "execution_time": "1368 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.set_phase(np.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 14, "result": "WA", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 15, "result": "WA", "execution_time": "1433 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 16, "result": "WA", "execution_time": "1419 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(np.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 17, "result": "WA", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(np.pi/2, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 18, "result": "WA", "execution_time": "1351 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    k = np.pi/2\n    qc.rz(k,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 19, "result": "WA", "execution_time": "1580 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    k = np.pi * 1/2\n    qc.rz(k,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 20, "result": "WA", "execution_time": "1464 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    k = np.pi * 3/2\n    qc.rz(k,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 21, "result": "WA", "execution_time": "1260 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    k = np.pi\n    qc.rx(k,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 22, "result": "WA", "execution_time": "1423 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    k = np.pi\n    qc.rz(k,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 23, "result": "WA", "execution_time": "1566 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    k = pi\n    qc.rz(k,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 24, "result": "WA", "execution_time": "1151 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    k = pi / 2\n    qc.rz(k,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 25, "result": "WA", "execution_time": "1388 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    k = pi / 2\n    qc.rz(k,0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A974216FBAAA9", "submission_order": 26, "result": "AC", "execution_time": "1090 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = pi\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A98C54F9BD5E2", "submission_order": 1, "result": "WA", "execution_time": "1556 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A98C54F9BD5E2", "submission_order": 2, "result": "WA", "execution_time": "1365 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A98C54F9BD5E2", "submission_order": 3, "result": "AC", "execution_time": "1373 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9A1D341A5E30", "submission_order": 1, "result": "WA", "execution_time": "1398 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9A1D341A5E30", "submission_order": 2, "result": "AC", "execution_time": "1384 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9C6DE340760E", "submission_order": 1, "result": "AC", "execution_time": "1060 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9CC22FDDEBCC", "submission_order": 1, "result": "WA", "execution_time": "1198 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9CC22FDDEBCC", "submission_order": 2, "result": "AC", "execution_time": "1525 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9DB5D372586A", "submission_order": 1, "result": "WA", "execution_time": "1385 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    # to do a phase flip from ket(0) to -ket(0) apply pauli z gate\n    # quantum_circit.z(qubit_index)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9DB5D372586A", "submission_order": 2, "result": "WA", "execution_time": "1377 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    # to do a phase flip from ket(0) to -ket(0) apply pauli z gate\n    # quantum_circit.z(qubit_index)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9E2239A49714", "submission_order": 1, "result": "WA", "execution_time": "1469 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "A9E2239A49714", "submission_order": 2, "result": "AC", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code her\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA07EC080FD01", "submission_order": 1, "result": "WA", "execution_time": "1399 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA07EC080FD01", "submission_order": 2, "result": "WA", "execution_time": "1440 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n   \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA07EC080FD01", "submission_order": 3, "result": "WA", "execution_time": "1909 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.s(0)  # Apply phase shift gate (S gate) to change the phase to -1\n    qc.x(0)  # Apply Pauli-X gate (X gate) to flip the state from |0⟩ to |1⟩\n    qc.x(0) \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA07EC080FD01", "submission_order": 4, "result": "WA", "execution_time": "1057 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0) \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA07EC080FD01", "submission_order": 5, "result": "WA", "execution_time": "1567 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA07EC080FD01", "submission_order": 6, "result": "RE", "execution_time": "1870 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.u1(-3.141592653589793, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA2C3660225A5", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA337AAD44346", "submission_order": 1, "result": "AC", "execution_time": "1802 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 1, "result": "WA", "execution_time": "1125 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 2, "result": "RE", "execution_time": "1356 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(pi,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 3, "result": "WA", "execution_time": "1049 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(pi,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 4, "result": "RE", "execution_time": "1312 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(pi,0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n     qc.u3(pi, 0, pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n     qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 7, "result": "WA", "execution_time": "1333 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(3.141592653589793, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 8, "result": "RE", "execution_time": "1415 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u3(3.141592653589793, 0, 3.141592653589793, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 9, "result": "WA", "execution_time": "1425 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 10, "result": "RE", "execution_time": "1895 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(np.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA354CF2BC789", "submission_order": 11, "result": "AC", "execution_time": "1485 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = 3.141592653589793\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA54D4CE5EA65", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA54D4CE5EA65", "submission_order": 2, "result": "AC", "execution_time": "1524 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA58E5218B4E8", "submission_order": 1, "result": "WA", "execution_time": "1422 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AA58E5218B4E8", "submission_order": 2, "result": "AC", "execution_time": "1407 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AAAA7E988ECCE", "submission_order": 1, "result": "AC", "execution_time": "2003 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AACEAB22CF681", "submission_order": 1, "result": "WA", "execution_time": "1218 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)  # Zゲートを量子ビット0に適用\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AACEAB22CF681", "submission_order": 2, "result": "RE", "execution_time": "1304 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.g(0)  # Zゲートを量子ビット0に適用\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AAD54747D6103", "submission_order": 1, "result": "AC", "execution_time": "1519 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AAE2443748FE9", "submission_order": 1, "result": "AC", "execution_time": "1106 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AAF30F3B30EF4", "submission_order": 1, "result": "AC", "execution_time": "1744 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AAFC132A9B7A0", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n\n\nif __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    import numpy as np\n    import random\n    qc = solve()\n    sv = Statevector(qc)\n#     sv = Statevector.from_label('+++')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_A1", "user": "AAFC132A9B7A0", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n\n\nif __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    import numpy as np\n    import random\n    qc = solve()\n    sv = Statevector(qc)\n#     sv = Statevector.from_label('+++')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_A1", "user": "AAFC132A9B7A0", "submission_order": 3, "result": "AC", "execution_time": "1801 ms", "memory": "158 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     import random\n#     qc = solve()\n#     sv = Statevector(qc)\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_A1", "user": "AB03262C6CB16", "submission_order": 1, "result": "WA", "execution_time": "1442 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB03262C6CB16", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.-i(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB0CD3B4DAEE4", "submission_order": 1, "result": "AC", "execution_time": "1360 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 1, "result": "WA", "execution_time": "1429 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 2, "result": "WA", "execution_time": "1406 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 3, "result": "WA", "execution_time": "1479 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 4, "result": "WA", "execution_time": "1315 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 5, "result": "WA", "execution_time": "1434 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 6, "result": "WA", "execution_time": "1572 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 7, "result": "RE", "execution_time": "1455 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(math.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 8, "result": "WA", "execution_time": "1568 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(math.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 9, "result": "WA", "execution_time": "1040 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 10, "result": "WA", "execution_time": "1549 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(math.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB1EEE7940B1E", "submission_order": 11, "result": "AC", "execution_time": "1492 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB3F1E10037C7", "submission_order": 1, "result": "AC", "execution_time": "1488 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AB8FF5AB86CE2", "submission_order": 1, "result": "RE", "execution_time": "1617 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.measure_all()\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABA5AC984BF17", "submission_order": 1, "result": "AC", "execution_time": "1433 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(2.0 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABC80057EF8F8", "submission_order": 1, "result": "WA", "execution_time": "1694 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABC80057EF8F8", "submission_order": 2, "result": "WA", "execution_time": "1656 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.z(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABC80057EF8F8", "submission_order": 3, "result": "AC", "execution_time": "1685 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABCAA7C4D31D4", "submission_order": 1, "result": "AC", "execution_time": "1462 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABE6FD6DC7189", "submission_order": 1, "result": "WA", "execution_time": "1343 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABE6FD6DC7189", "submission_order": 2, "result": "WA", "execution_time": "1177 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABE6FD6DC7189", "submission_order": 3, "result": "RE", "execution_time": "1342 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # qc.x(0)\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABE6FD6DC7189", "submission_order": 4, "result": "WA", "execution_time": "1344 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABEC701C88CE3", "submission_order": 1, "result": "RE", "execution_time": "1427 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABEC701C88CE3", "submission_order": 2, "result": "WA", "execution_time": "1073 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABEC701C88CE3", "submission_order": 3, "result": "AC", "execution_time": "1425 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ABF49E035483C", "submission_order": 1, "result": "AC", "execution_time": "1691 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC011789291C0", "submission_order": 1, "result": "RE", "execution_time": "1716 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x()\n    qc.z()\n    qc.x()\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC011789291C0", "submission_order": 2, "result": "RE", "execution_time": "1754 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC011789291C0", "submission_order": 3, "result": "AC", "execution_time": "1825 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC0C5427184D3", "submission_order": 1, "result": "WA", "execution_time": "1390 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC0C5427184D3", "submission_order": 2, "result": "WA", "execution_time": "1127 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.h(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC0C5427184D3", "submission_order": 3, "result": "AC", "execution_time": "1622 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1541C44C8B7", "submission_order": 1, "result": "AC", "execution_time": "1412 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1595D25F190", "submission_order": 1, "result": "AC", "execution_time": "1480 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC188CB68491D", "submission_order": 1, "result": "AC", "execution_time": "1271 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1A043FA7E1A", "submission_order": 1, "result": "WA", "execution_time": "1147 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1A043FA7E1A", "submission_order": 2, "result": "WA", "execution_time": "1390 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.reset(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1A043FA7E1A", "submission_order": 3, "result": "WA", "execution_time": "1437 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1A043FA7E1A", "submission_order": 4, "result": "WA", "execution_time": "1342 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1A043FA7E1A", "submission_order": 5, "result": "AC", "execution_time": "1044 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1BABC3EC677", "submission_order": 1, "result": "RE", "execution_time": "1623 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1BABC3EC677", "submission_order": 2, "result": "RE", "execution_time": "1042 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC1BABC3EC677", "submission_order": 3, "result": "AC", "execution_time": "1890 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC3B209F8F01D", "submission_order": 1, "result": "AC", "execution_time": "1491 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC8ABFB7AD157", "submission_order": 1, "result": "AC", "execution_time": "1346 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC8CF19DFE14F", "submission_order": 1, "result": "WA", "execution_time": "1195 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC8CF19DFE14F", "submission_order": 2, "result": "WA", "execution_time": "1142 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AC8CF19DFE14F", "submission_order": 3, "result": "AC", "execution_time": "1138 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ACC826E40F93A", "submission_order": 1, "result": "AC", "execution_time": "1928 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ACD7787A419C0", "submission_order": 1, "result": "RE", "execution_time": "1142 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return -qc\n'''"}
{"problem": "QPC002_A1", "user": "ACD7787A419C0", "submission_order": 2, "result": "RE", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = -qc\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ACD7787A419C0", "submission_order": 3, "result": "WA", "execution_time": "1045 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ACD7787A419C0", "submission_order": 4, "result": "WA", "execution_time": "1362 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ACD7787A419C0", "submission_order": 5, "result": "AC", "execution_time": "1413 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ACF1E3B137A65", "submission_order": 1, "result": "WA", "execution_time": "1893 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ACF1E3B137A65", "submission_order": 2, "result": "WA", "execution_time": "1901 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ACF1E3B137A65", "submission_order": 3, "result": "AC", "execution_time": "1936 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD1476A6E97D4", "submission_order": 1, "result": "RE", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(i)\n    qc.z(i)\n    qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD1476A6E97D4", "submission_order": 2, "result": "RE", "execution_time": "1390 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD1476A6E97D4", "submission_order": 3, "result": "AC", "execution_time": "1337 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD2A9C2CB2C2F", "submission_order": 1, "result": "AC", "execution_time": "1432 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD3BB58A67ECB", "submission_order": 1, "result": "AC", "execution_time": "1188 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD4F448E42ECA", "submission_order": 1, "result": "WA", "execution_time": "1373 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD4F448E42ECA", "submission_order": 2, "result": "AC", "execution_time": "1262 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD4FD94C74975", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(1)\n\tqc.x(0)\n\tqc.z(0)\n\tqc.x(0)\n\treturn qc\n\nif __name__ == \"__main__\":\n\tfrom Qiskit_Library import *\n\tqc = solve()\n\tprint_circuit_matrix(qc)\n\tprint_circuit_nonzero(qc)\n\tprint_circuit_output(qc, [1, 0])\n'''"}
{"problem": "QPC002_A1", "user": "AD4FD94C74975", "submission_order": 2, "result": "AC", "execution_time": "1900 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(1)\n\tqc.x(0)\n\tqc.z(0)\n\tqc.x(0)\n\treturn qc\n'''"}
{"problem": "QPC002_A1", "user": "AD6503253CC88", "submission_order": 1, "result": "AC", "execution_time": "1509 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.r(2*math.pi, 0, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD73CA3EADE60", "submission_order": 1, "result": "AC", "execution_time": "1366 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD7A205AA2246", "submission_order": 1, "result": "WA", "execution_time": "1583 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD7A205AA2246", "submission_order": 2, "result": "AC", "execution_time": "1588 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD83664DA50D5", "submission_order": 1, "result": "WA", "execution_time": "1862 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD83664DA50D5", "submission_order": 2, "result": "RE", "execution_time": "1740 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc.z(0)\n'''"}
{"problem": "QPC002_A1", "user": "AD83664DA50D5", "submission_order": 3, "result": "WA", "execution_time": "1674 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD83664DA50D5", "submission_order": 4, "result": "AC", "execution_time": "1670 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 1, "result": "RE", "execution_time": "1133 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 2, "result": "WA", "execution_time": "1465 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 3, "result": "WA", "execution_time": "1449 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(math.pi, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 4, "result": "RE", "execution_time": "1037 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 5, "result": "RE", "execution_time": "1034 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 6, "result": "WA", "execution_time": "1341 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 7, "result": "WA", "execution_time": "1754 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 8, "result": "RE", "execution_time": "1325 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.g(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 9, "result": "WA", "execution_time": "1570 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.s(0)\n    qc.s(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 10, "result": "RE", "execution_time": "1579 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.z(1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 11, "result": "RE", "execution_time": "1473 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 12, "result": "WA", "execution_time": "1641 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    qc.s(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 13, "result": "WA", "execution_time": "1629 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 14, "result": "WA", "execution_time": "1285 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 15, "result": "RE", "execution_time": "1676 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 16, "result": "RE", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 17, "result": "RE", "execution_time": "1404 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 18, "result": "RE", "execution_time": "1084 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9252E912469", "submission_order": 19, "result": "WA", "execution_time": "1582 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9FD746D6C88", "submission_order": 1, "result": "RE", "execution_time": "1579 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9FD746D6C88", "submission_order": 2, "result": "WA", "execution_time": "1424 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9FD746D6C88", "submission_order": 3, "result": "WA", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9FD746D6C88", "submission_order": 4, "result": "WA", "execution_time": "1056 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9FD746D6C88", "submission_order": 5, "result": "WA", "execution_time": "1950 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AD9FD746D6C88", "submission_order": 6, "result": "AC", "execution_time": "1408 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADA827E4C5030", "submission_order": 1, "result": "WA", "execution_time": "1127 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADA827E4C5030", "submission_order": 2, "result": "AC", "execution_time": "1442 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADB681EC69B16", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC002_A1", "user": "ADB681EC69B16", "submission_order": 2, "result": "AC", "execution_time": "1705 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A1", "user": "ADC7604D4E5B5", "submission_order": 1, "result": "WA", "execution_time": "1514 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADC7604D4E5B5", "submission_order": 2, "result": "WA", "execution_time": "1171 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADC7604D4E5B5", "submission_order": 3, "result": "WA", "execution_time": "1203 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Z gate to create the state -|0>\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADC7604D4E5B5", "submission_order": 4, "result": "AC", "execution_time": "1515 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Z gate to create the state -|0>\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADCC9397E9B51", "submission_order": 1, "result": "RE", "execution_time": "1380 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h()\n    qc.x()\n    qc.h()\n    qc.x\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADCC9397E9B51", "submission_order": 2, "result": "WA", "execution_time": "1380 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.h(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADCC9397E9B51", "submission_order": 3, "result": "WA", "execution_time": "1421 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.h(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADCC9397E9B51", "submission_order": 4, "result": "AC", "execution_time": "1364 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADCD393033647", "submission_order": 1, "result": "AC", "execution_time": "1529 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # Apply PauliX gate and PauliZ gate to the 1st qubit (index 0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADCE8EE6960FD", "submission_order": 1, "result": "AC", "execution_time": "1380 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADD01F23BB439", "submission_order": 1, "result": "WA", "execution_time": "1981 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADD01F23BB439", "submission_order": 2, "result": "AC", "execution_time": "1889 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADE42277324F7", "submission_order": 1, "result": "WA", "execution_time": "1048 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADE42277324F7", "submission_order": 2, "result": "WA", "execution_time": "1536 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADE42277324F7", "submission_order": 3, "result": "AC", "execution_time": "1438 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "ADEC951442B2F", "submission_order": 1, "result": "AC", "execution_time": "1490 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AE3A07F499F24", "submission_order": 1, "result": "AC", "execution_time": "1149 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AE8DFFD614CB8", "submission_order": 1, "result": "WA", "execution_time": "1881 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AE8DFFD614CB8", "submission_order": 2, "result": "RE", "execution_time": "1607 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.g(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AE8DFFD614CB8", "submission_order": 3, "result": "WA", "execution_time": "1806 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AE9025EE32B75", "submission_order": 1, "result": "AC", "execution_time": "1367 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AE9CC59EF0D1E", "submission_order": 1, "result": "WA", "execution_time": "2005 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AE9CC59EF0D1E", "submission_order": 2, "result": "AC", "execution_time": "1964 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AEB35676A4906", "submission_order": 1, "result": "WA", "execution_time": "2113 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Z gate to the qubit\n    qc.z(0)  # This will effectively prepare the state -|0>\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AEB35676A4906", "submission_order": 2, "result": "AC", "execution_time": "2232 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Z gate to the qubit\n    qc.x(0)\n    qc.z(0)  # This will effectively prepare the state -|0>\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AEBD280C56027", "submission_order": 1, "result": "AC", "execution_time": "1541 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.global_phase = pi \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AEC1A2DB1C116", "submission_order": 1, "result": "WA", "execution_time": "1426 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AEC1A2DB1C116", "submission_order": 2, "result": "RE", "execution_time": "1204 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = -qc\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AEC1A2DB1C116", "submission_order": 3, "result": "AC", "execution_time": "1452 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AEC3C5A1CF229", "submission_order": 1, "result": "AC", "execution_time": "1930 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF0377296CD50", "submission_order": 1, "result": "RE", "execution_time": "1288 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(2 * math.PI, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF0377296CD50", "submission_order": 2, "result": "AC", "execution_time": "1400 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(2 * math.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF17AC244C22F", "submission_order": 1, "result": "AC", "execution_time": "1490 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    # Flip the qubit to |1⟩\n    qc.x(0)\n    \n    # Apply phase shift of π\n    qc.z(0)\n    \n    # Flip the qubit back to |0⟩\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF49D6B7B5448", "submission_order": 1, "result": "RE", "execution_time": "1335 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(np.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF49D6B7B5448", "submission_order": 2, "result": "WA", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(np.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF49D6B7B5448", "submission_order": 3, "result": "WA", "execution_time": "1468 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(0, 0, np.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF49D6B7B5448", "submission_order": 4, "result": "AC", "execution_time": "1579 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF57E9F58FAC4", "submission_order": 1, "result": "WA", "execution_time": "1494 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF57F5784C35B", "submission_order": 1, "result": "AC", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF76C5DED6360", "submission_order": 1, "result": "AC", "execution_time": "1203 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF8B4662983EC", "submission_order": 1, "result": "WA", "execution_time": "1205 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF8B4662983EC", "submission_order": 2, "result": "AC", "execution_time": "1357 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9C2664717DA", "submission_order": 1, "result": "RE", "execution_time": "1474 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi, 1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9C2664717DA", "submission_order": 2, "result": "RE", "execution_time": "1414 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi, 1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9C2664717DA", "submission_order": 3, "result": "RE", "execution_time": "1351 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9C2664717DA", "submission_order": 4, "result": "RE", "execution_time": "1464 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9C2664717DA", "submission_order": 5, "result": "WA", "execution_time": "1485 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9C2664717DA", "submission_order": 6, "result": "RE", "execution_time": "1112 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9C2664717DA", "submission_order": 7, "result": "WA", "execution_time": "1466 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    import numpy as np\n    # Write your code here:\n    qc.rx(np.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9C2664717DA", "submission_order": 8, "result": "AC", "execution_time": "1421 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9E15288D73F", "submission_order": 1, "result": "AC", "execution_time": "1408 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9F24C567580", "submission_order": 1, "result": "RE", "execution_time": "1569 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.X(1)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9F24C567580", "submission_order": 2, "result": "WA", "execution_time": "1135 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9F24C567580", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AF9F24C567580", "submission_order": 4, "result": "AC", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AFB76DD85D69A", "submission_order": 1, "result": "AC", "execution_time": "1592 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AFE468478299D", "submission_order": 1, "result": "RE", "execution_time": "1548 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x[0]\n    qc.z[0]\n    qc.x[0]\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AFE468478299D", "submission_order": 2, "result": "RE", "execution_time": "1082 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc0=qc = QuantumCircuit(q)\n    qc.x[0]\n    qc.z[0]\n    qc.x[0]\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AFE468478299D", "submission_order": 3, "result": "RE", "execution_time": "1436 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc0=QuantumCircuit(q)\n    qc0.x[0]\n    qc0.z[0]\n    qc0.x[0]\n    return qc\n'''"}
{"problem": "QPC002_A1", "user": "AFE468478299D", "submission_order": 4, "result": "AC", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0036941E907E", "submission_order": 1, "result": "WA", "execution_time": "1479 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0036941E907E", "submission_order": 2, "result": "WA", "execution_time": "1774 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0036941E907E", "submission_order": 3, "result": "WA", "execution_time": "1409 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0266DFAEC932", "submission_order": 1, "result": "AC", "execution_time": "1564 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0858E0F58AC7", "submission_order": 1, "result": "AC", "execution_time": "1099 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0);\n    qc.h(0);\n    qc.cx(0, 1);\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A08ACACE8BD1C", "submission_order": 1, "result": "AC", "execution_time": "1449 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Apply Hadamard gate to the first qubit to create superposition\n    qc.h(0)\n    \n    # Apply CNOT gate with control qubit 0 and target qubit 1\n    qc.cx(0, 1)\n    \n    # Apply Z gate to the first qubit to introduce phase difference\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0A7C8834F793", "submission_order": 1, "result": "AC", "execution_time": "1369 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    # qc.cx(control qubit, target qubit)\n    qc.cx(0, 1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0F7953A1519F", "submission_order": 1, "result": "AC", "execution_time": "1504 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0FD4D930CDFB", "submission_order": 1, "result": "WA", "execution_time": "1234 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0FD4D930CDFB", "submission_order": 2, "result": "WA", "execution_time": "1344 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A0FD4D930CDFB", "submission_order": 3, "result": "AC", "execution_time": "1063 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A12DA7E973DB2", "submission_order": 1, "result": "WA", "execution_time": "1141 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A12DA7E973DB2", "submission_order": 2, "result": "AC", "execution_time": "1048 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A138CD18A9E16", "submission_order": 1, "result": "WA", "execution_time": "1051 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A138CD18A9E16", "submission_order": 2, "result": "WA", "execution_time": "1361 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A138CD18A9E16", "submission_order": 3, "result": "WA", "execution_time": "1468 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A138CD18A9E16", "submission_order": 4, "result": "AC", "execution_time": "1402 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    # qc.cx(control qubit, target qubit)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A15C684ECC4DE", "submission_order": 1, "result": "WA", "execution_time": "1733 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A15C684ECC4DE", "submission_order": 2, "result": "AC", "execution_time": "1657 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A17114E46F7AD", "submission_order": 1, "result": "WA", "execution_time": "1416 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0,1])\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A17114E46F7AD", "submission_order": 2, "result": "AC", "execution_time": "1355 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A17AEAEA92985", "submission_order": 1, "result": "WA", "execution_time": "1431 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A17AEAEA92985", "submission_order": 2, "result": "AC", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.crx(2*math.pi,0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A18997AAB603F", "submission_order": 1, "result": "WA", "execution_time": "1914 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A18997AAB603F", "submission_order": 2, "result": "WA", "execution_time": "1952 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h([0, 1])\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A18997AAB603F", "submission_order": 3, "result": "AC", "execution_time": "1935 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A18EA1C2247B3", "submission_order": 1, "result": "AC", "execution_time": "1921 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 1, "result": "WA", "execution_time": "1077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.z(0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 2, "result": "WA", "execution_time": "1522 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 3, "result": "WA", "execution_time": "1094 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 4, "result": "WA", "execution_time": "1067 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 5, "result": "WA", "execution_time": "1132 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 6, "result": "WA", "execution_time": "1605 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 7, "result": "WA", "execution_time": "1498 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 8, "result": "WA", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 9, "result": "WA", "execution_time": "1178 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.h(1)\n    qc.x(0)\n    qc.z(0)\n    qc.x(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 10, "result": "WA", "execution_time": "1168 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.x(1)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1A75219744F1", "submission_order": 11, "result": "AC", "execution_time": "1032 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1AD360A7ABCA", "submission_order": 1, "result": "AC", "execution_time": "1862 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A2", "user": "A1DCE57DF11F0", "submission_order": 1, "result": "WA", "execution_time": "1481 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1DCE57DF11F0", "submission_order": 2, "result": "WA", "execution_time": "1038 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1DCE57DF11F0", "submission_order": 3, "result": "WA", "execution_time": "1337 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1DCE57DF11F0", "submission_order": 4, "result": "WA", "execution_time": "1364 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1DCE57DF11F0", "submission_order": 5, "result": "WA", "execution_time": "1483 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h([0, 1])\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1DCE57DF11F0", "submission_order": 6, "result": "WA", "execution_time": "1387 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1DCE57DF11F0", "submission_order": 7, "result": "WA", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1DCE57DF11F0", "submission_order": 8, "result": "AC", "execution_time": "1438 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1EA774F07B84", "submission_order": 1, "result": "AC", "execution_time": "1841 ms", "memory": "158 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     import random\n#     qc = solve()\n#     sv = Statevector(qc)\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_A2", "user": "A1F4A11C4E9E8", "submission_order": 1, "result": "WA", "execution_time": "1491 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A1F4A11C4E9E8", "submission_order": 2, "result": "AC", "execution_time": "1481 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n\n    qc.z(1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A20D67047C217", "submission_order": 1, "result": "AC", "execution_time": "1044 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A2259CFA004CE", "submission_order": 1, "result": "RE", "execution_time": "1424 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qx.cx(0,1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A2259CFA004CE", "submission_order": 2, "result": "AC", "execution_time": "1545 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A22B166466E85", "submission_order": 1, "result": "AC", "execution_time": "1084 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A24C9B9C5DC3B", "submission_order": 1, "result": "WA", "execution_time": "1384 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A24C9B9C5DC3B", "submission_order": 2, "result": "AC", "execution_time": "1405 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A291FB798CCCD", "submission_order": 1, "result": "RE", "execution_time": "1252 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cnot(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A291FB798CCCD", "submission_order": 2, "result": "AC", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A29F73CD0B478", "submission_order": 1, "result": "AC", "execution_time": "1171 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A2ADA9E9E3F83", "submission_order": 1, "result": "WA", "execution_time": "1996 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A2ADA9E9E3F83", "submission_order": 2, "result": "AC", "execution_time": "1921 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A2F228B58F2E5", "submission_order": 1, "result": "AC", "execution_time": "1349 ms", "memory": "154 MiB", "code": "'''python\nimport math\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import (\n    C3XGate,\n    C3SXGate,\n    C4XGate,\n    CCXGate,\n    DCXGate,\n    CHGate,\n    CPhaseGate,\n    CRXGate,\n    CRYGate,\n    CRZGate,\n    CSwapGate,\n    CSXGate,\n    CUGate,\n    CU1Gate,\n    CU3Gate,\n    CXGate,\n    CYGate,\n    CZGate,\n    CCZGate,\n    HGate,\n    IGate,\n    MCPhaseGate,\n    PhaseGate,\n    RCCXGate,\n    RC3XGate,\n    RXGate,\n    RXXGate,\n    RYGate,\n    RYYGate,\n    RZGate,\n    RZZGate,\n    RZXGate,\n    XXMinusYYGate,\n    XXPlusYYGate,\n    ECRGate,\n    SGate,\n    SdgGate,\n    CSGate,\n    CSdgGate,\n    SwapGate,\n    iSwapGate,\n    SXGate,\n    SXdgGate,\n    TGate,\n    TdgGate,\n    UGate,\n    U1Gate,\n    U2Gate,\n    U3Gate,\n    XGate,\n    YGate,\n    ZGate,\n)\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A2F2CBED109BD", "submission_order": 1, "result": "AC", "execution_time": "1382 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A2FE0F38D86C1", "submission_order": 1, "result": "AC", "execution_time": "1837 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\tqc.x(0)\n\tqc.h(0)\n\tqc.cx(0, 1)\n\treturn qc\n'''"}
{"problem": "QPC002_A2", "user": "A30140D2B3D28", "submission_order": 1, "result": "AC", "execution_time": "1139 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3279DB61487A", "submission_order": 1, "result": "AC", "execution_time": "1755 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A32F0310AE61F", "submission_order": 1, "result": "AC", "execution_time": "1472 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A35B6794D5CA7", "submission_order": 1, "result": "AC", "execution_time": "1523 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A376AA5C73D9B", "submission_order": 1, "result": "AC", "execution_time": "1727 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3937AC0239AE", "submission_order": 1, "result": "AC", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3AB8F62F2C83", "submission_order": 1, "result": "WA", "execution_time": "1879 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3AB8F62F2C83", "submission_order": 2, "result": "WA", "execution_time": "1109 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3AD5DE3FE463", "submission_order": 1, "result": "WA", "execution_time": "1171 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3AD5DE3FE463", "submission_order": 2, "result": "AC", "execution_time": "1671 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3BF6992024DC", "submission_order": 1, "result": "RE", "execution_time": "1333 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3BF6992024DC", "submission_order": 2, "result": "AC", "execution_time": "1187 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3D8E9CB330AA", "submission_order": 1, "result": "WA", "execution_time": "1705 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.z(0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3D8E9CB330AA", "submission_order": 2, "result": "AC", "execution_time": "1391 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3E04DA1C7549", "submission_order": 1, "result": "AC", "execution_time": "1915 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A3EBF70CB6DDB", "submission_order": 1, "result": "AC", "execution_time": "1077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0) \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4164DF294E50", "submission_order": 1, "result": "RE", "execution_time": "1413 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(2):\n        qc.x(i)\n    qc.h(0)\n    qc.x(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4164DF294E50", "submission_order": 2, "result": "WA", "execution_time": "1374 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(2):\n        qc.x(i)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4164DF294E50", "submission_order": 3, "result": "WA", "execution_time": "1416 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4164DF294E50", "submission_order": 4, "result": "AC", "execution_time": "1480 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A41775C93BE45", "submission_order": 1, "result": "AC", "execution_time": "1540 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n_bits)\n    qc.h(0)\n    m = 0\n    while 1 << m < n_bits: m += 1\n    for k in range(m):\n        d = 1 << k\n        for i in range(d):\n            if i + d < n_bits: qc.cx(i, i + d)\n    return qc\n\n\ndef solve() -> QuantumCircuit:\n    qc = get_ghz_circuit(2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A44D5D80FFF97", "submission_order": 1, "result": "AC", "execution_time": "1960 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A459773AE9241", "submission_order": 1, "result": "WA", "execution_time": "1903 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.dcx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A459773AE9241", "submission_order": 2, "result": "AC", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A459C1C15C385", "submission_order": 1, "result": "RE", "execution_time": "1398 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A459C1C15C385", "submission_order": 2, "result": "AC", "execution_time": "1368 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A482330088C3A", "submission_order": 1, "result": "AC", "execution_time": "1440 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.z(1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A48F05C4121FF", "submission_order": 1, "result": "AC", "execution_time": "1185 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4ADD9A608669", "submission_order": 1, "result": "RE", "execution_time": "1777 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.p(pi, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4ADD9A608669", "submission_order": 2, "result": "RE", "execution_time": "1761 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.p(pi, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4ADD9A608669", "submission_order": 3, "result": "AC", "execution_time": "1910 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.p(math.pi, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4D11B3C6AC79", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:]\n     qc.x(0)       \n     qc.h(1)       \n     qc.cz(0, 1)    \n     qc.x(0)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4D11B3C6AC79", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:]\n     qc.x(0)       \n     qc.h(1)       \n     qc.cx(1,0)    \n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4D11B3C6AC79", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:]\n     qc.x(1)       \n     qc.h(0)       \n     qc.cx(1,0)    \n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4D11B3C6AC79", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:]\n     qc.x(0)       \n     qc.h(0)       \n     qc.cx(0,1)    \n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4D11B3C6AC79", "submission_order": 5, "result": "AC", "execution_time": "1464 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:]\n    qc.x(0)       \n    qc.h(0)       \n    qc.cx(0,1)    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 1, "result": "WA", "execution_time": "1410 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ch(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 2, "result": "WA", "execution_time": "1518 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 3, "result": "RE", "execution_time": "1418 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.c(0,1)\n    qc.append(ZGate().control(1), range(2))\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 4, "result": "RE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.c(0,1)\n    qc.append(ZGate().control(1), range(2))\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 5, "result": "RE", "execution_time": "1344 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.c(0,1)\n    qc.append(ZGate().control(1), range(2))\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 6, "result": "RE", "execution_time": "1084 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.c(0,1)\n    qc.append(ZGate().control(0))\n    qc.append(ZGate().control(1))\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 7, "result": "RE", "execution_time": "1401 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.c(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 8, "result": "RE", "execution_time": "1551 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.c(0,1)\n    for i in range(2):\n        qc.append(ZGate().control(i-1))\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 9, "result": "RE", "execution_time": "1457 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.c(0,1)\n    qc.append(ZGate().control(0))\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4EB89C19F121", "submission_order": 10, "result": "AC", "execution_time": "1190 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A4FACA9643804", "submission_order": 1, "result": "AC", "execution_time": "1528 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A503F9744742F", "submission_order": 1, "result": "AC", "execution_time": "1390 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A52280B80EAF4", "submission_order": 1, "result": "AC", "execution_time": "1464 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gate with the first qubit as control and second as target\n    qc.cx(0, 1)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A53A33B970A78", "submission_order": 1, "result": "AC", "execution_time": "1364 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A53C590B93E0C", "submission_order": 1, "result": "RE", "execution_time": "1386 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    # Write your code here:\n    # |-> \n\n    qc = QuantumCircuit(2)\n    q = QuantumRegister(2,'q')\n    qc.x(q[0])\n    qc.h(q[0])\n    #\n    # |->    \n    # |0> \n\n\n    qc.cnot(q[0],q[1])\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A53C590B93E0C", "submission_order": 2, "result": "RE", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    # Write your code here:\n    # |-> \n\n    qc = QuantumCircuit(2)\n    q = QuantumRegister(2,'q')\n    qc.x(q[0])\n    qc.h(q[0])\n    #\n    # |->    \n    # |0> \n    qc.cx(q[0],q[1])\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A53C590B93E0C", "submission_order": 3, "result": "RE", "execution_time": "1396 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    # Write your code here:\n    qc = QuantumCircuit(2)\n    q = QuantumRegister(2,'q')\n    qc.x(q[0])\n    qc.h(q[0])\n    qc.c(q[0],q[1])\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A53C590B93E0C", "submission_order": 4, "result": "RE", "execution_time": "1464 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    # Write your code here:\n    qc = QuantumCircuit(2)\n    q = QuantumRegister(2,'q')\n    qc.x(q[0])\n    qc.h(q[0])\n    qc.c(q[0],q[1])\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A53C590B93E0C", "submission_order": 5, "result": "RE", "execution_time": "1437 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    # Write your code here:\n    qc = QuantumCircuit(2)\n    q = QuantumRegister(2,'q')\n    qc.x(q[0])\n    qc.h(q[0])\n    qc.cnot(q[0],q[1])\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A53C590B93E0C", "submission_order": 6, "result": "AC", "execution_time": "1419 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    # Write your code here:\n    qc = QuantumCircuit(2)\n    q = QuantumRegister(2,'q')\n    qc.x(q[0])\n    qc.h(q[0])\n    qc.cx(q[0],q[1])\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A54049431254C", "submission_order": 1, "result": "AC", "execution_time": "1444 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A548EEDDD2CBC", "submission_order": 1, "result": "AC", "execution_time": "1392 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A57245C65A896", "submission_order": 1, "result": "WA", "execution_time": "1806 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    qc.h(0) # 1/sqrt(2) * (|00> + |10>)\n    qc.cx(0, 1) # 1/sqrt(2) * (|00> + |11>)\n    qc.x(0) # |01> - |10>\n    qc.h(0) # 1/sqrt(2) * (|01> - |11>)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A57245C65A896", "submission_order": 2, "result": "WA", "execution_time": "1520 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    qc.h(0) # 1/sqrt(2) * (|00> + |10>)\n    qc.cx(0, 1) # 1/sqrt(2) * (|00> + |11>)\n    qc.h(0) # 1/sqrt(2) * (|01> - |11>)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A57245C65A896", "submission_order": 3, "result": "AC", "execution_time": "1409 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    qc.h(0) # 1/sqrt(2) * (|00> + |10>)\n    qc.cx(0, 1) # 1/sqrt(2) * (|00> + |11>)\n    qc.z(1) # 1/sqrt(2) * (|00> - |11>)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A58D13CA556AF", "submission_order": 1, "result": "RE", "execution_time": "1365 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = get_ghz_circuit(2)\n    qc.z(0)\n\n    return qc\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    #Calculate i using bit length\n    i = (n_bits-1).bit_length\n\n    for k in range(i):\n        d = 2**k\n        for b in range(d):\n            if b+d < n_bits:\n                qc.cx(b,b+d)\n        \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A58D13CA556AF", "submission_order": 2, "result": "RE", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    #Calculate i using bit length\n    i = (n_bits-1).bit_length\n\n    for k in range(i):\n        d = 2**k\n        for b in range(d):\n            if b+d < n_bits:\n                qc.cx(b,b+d)\n        \n    return qc\n\ndef solve() -> QuantumCircuit:\n    qc = get_ghz_circuit(2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A58D13CA556AF", "submission_order": 3, "result": "RE", "execution_time": "1460 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    #Calculate i using bit length\n    i=0\n    i = (n_bits-1).bit_length\n\n    for k in range(i):\n        d = pow(2,k)\n        for b in range(d):\n            if b+d < n_bits:\n                qc.cx(b,b+d)\n        \n    return qc\n\ndef solve() -> QuantumCircuit:\n    qc = get_ghz_circuit(2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A58D13CA556AF", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    #Calculate i using bit length\n    i=0\n    i = 1<<i<n_bits:i+=1\n\n    for k in range(i):\n        d = pow(2,k)\n        for b in range(d):\n            if b+d < n_bits:\n                qc.cx(b,b+d)\n        \n    return qc\n\ndef solve() -> QuantumCircuit:\n    qc = get_ghz_circuit(2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A58D13CA556AF", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    #Calculate i using bit length\n    i=0\n    i = 1<<i<n_bits:+=1\n\n    for k in range(i):\n        d = 1<<k\n        for b in range(d):\n            if b+d < n_bits:qc.cx(b,b+d)\n    return qc\n\ndef solve() -> QuantumCircuit:\n    qc = get_ghz_circuit(2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A58D13CA556AF", "submission_order": 6, "result": "AC", "execution_time": "1356 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    #Calculate i using bit length\n    i=0\n    while 1<<i<n_bits:\n        i+=1\n\n    for k in range(i):\n        d = 1<<k\n        for b in range(d):\n            if b+d < n_bits:qc.cx(b,b+d)\n    return qc\n\ndef solve() -> QuantumCircuit:\n    qc = get_ghz_circuit(2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5B83098BB534", "submission_order": 1, "result": "AC", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5BAE7740C13E", "submission_order": 1, "result": "WA", "execution_time": "1638 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5BAE7740C13E", "submission_order": 2, "result": "AC", "execution_time": "1031 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5BDC89F675E5", "submission_order": 1, "result": "AC", "execution_time": "1483 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5D83610D4079", "submission_order": 1, "result": "WA", "execution_time": "1454 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5D83610D4079", "submission_order": 2, "result": "AC", "execution_time": "1538 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5DD0D8078E97", "submission_order": 1, "result": "WA", "execution_time": "1379 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    # Apply Controlled-Z gate to the qubits\n    qc.cz(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5DD0D8078E97", "submission_order": 2, "result": "AC", "execution_time": "1404 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    # Apply CNOT gate (control=0, target=1)\n    qc.cx(0, 1)\n    # Apply Z gate to the second qubit to introduce a phase flip\n    qc.z(1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A5ED5937C322C", "submission_order": 1, "result": "AC", "execution_time": "1114 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A60ADD7A1208E", "submission_order": 1, "result": "WA", "execution_time": "1466 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A60ADD7A1208E", "submission_order": 2, "result": "WA", "execution_time": "1466 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A60ADD7A1208E", "submission_order": 3, "result": "AC", "execution_time": "1855 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A610739FA6A36", "submission_order": 1, "result": "AC", "execution_time": "1402 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A6136D304CA92", "submission_order": 1, "result": "AC", "execution_time": "1716 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A64BBC4D15A76", "submission_order": 1, "result": "AC", "execution_time": "1427 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A64FA29E98198", "submission_order": 1, "result": "AC", "execution_time": "1637 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A65FB9E429551", "submission_order": 1, "result": "RE", "execution_time": "1119 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    qc.x(0)\n    qc.x(1)\n    qc.z(1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A65FB9E429551", "submission_order": 2, "result": "AC", "execution_time": "1404 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.x(1)\n    qc.z(1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A664C142B8EBE", "submission_order": 1, "result": "AC", "execution_time": "1230 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A66800E47FD60", "submission_order": 1, "result": "AC", "execution_time": "1649 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A6D6823B041CD", "submission_order": 1, "result": "AC", "execution_time": "2055 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A6F15A6B1926C", "submission_order": 1, "result": "AC", "execution_time": "1469 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A702A0979CB26", "submission_order": 1, "result": "AC", "execution_time": "1136 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A719307EF3DE6", "submission_order": 1, "result": "AC", "execution_time": "1178 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n#from qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.rxx(np.pi/2,0,1)\n    qc.cp(np.pi*3/2,0,1)\n\n    return qc\n\nqc = solve()\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_A2", "user": "A726CEA89D485", "submission_order": 1, "result": "AC", "execution_time": "1802 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A737D1F337EAA", "submission_order": 1, "result": "WA", "execution_time": "1504 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A737D1F337EAA", "submission_order": 2, "result": "AC", "execution_time": "1056 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A768D5B173903", "submission_order": 1, "result": "WA", "execution_time": "1623 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A768D5B173903", "submission_order": 2, "result": "RE", "execution_time": "2000 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(2)\n    qc.h(2)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A768D5B173903", "submission_order": 3, "result": "RE", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(2)\n    qc.h(2)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A768D5B173903", "submission_order": 4, "result": "AC", "execution_time": "1583 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A77580817D0CC", "submission_order": 1, "result": "WA", "execution_time": "1969 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A77580817D0CC", "submission_order": 2, "result": "AC", "execution_time": "1912 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A795AA0F5257A", "submission_order": 1, "result": "AC", "execution_time": "1531 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A7C41CDD1F601", "submission_order": 1, "result": "AC", "execution_time": "1385 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A7F90B8CB8DD5", "submission_order": 1, "result": "AC", "execution_time": "1592 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import GlobalPhaseGate\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.x(0)\n  qc.h(0)\n  qc.cx(0, 1)\n  return qc\n'''"}
{"problem": "QPC002_A2", "user": "A7FD2386D0A08", "submission_order": 1, "result": "WA", "execution_time": "1357 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A7FD2386D0A08", "submission_order": 2, "result": "WA", "execution_time": "1338 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.z(0)\n    qc.h(1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A7FD2386D0A08", "submission_order": 3, "result": "RE", "execution_time": "1172 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A7FD2386D0A08", "submission_order": 4, "result": "WA", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A7FD2386D0A08", "submission_order": 5, "result": "WA", "execution_time": "1350 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A7FD2386D0A08", "submission_order": 6, "result": "AC", "execution_time": "1525 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8143E69D8ADA", "submission_order": 1, "result": "WA", "execution_time": "1418 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8143E69D8ADA", "submission_order": 2, "result": "WA", "execution_time": "1467 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8143E69D8ADA", "submission_order": 3, "result": "WA", "execution_time": "1160 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8143E69D8ADA", "submission_order": 4, "result": "AC", "execution_time": "1085 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A817222AE9281", "submission_order": 1, "result": "AC", "execution_time": "1379 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A83637D37C4F2", "submission_order": 1, "result": "AC", "execution_time": "1110 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A84BB3A104EF5", "submission_order": 1, "result": "AC", "execution_time": "1987 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A850CD4A66853", "submission_order": 1, "result": "WA", "execution_time": "1490 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A850CD4A66853", "submission_order": 2, "result": "WA", "execution_time": "1129 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,0)\n    qc.z(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A850CD4A66853", "submission_order": 3, "result": "AC", "execution_time": "1446 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8666CF8F0713", "submission_order": 1, "result": "RE", "execution_time": "1722 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8666CF8F0713", "submission_order": 2, "result": "AC", "execution_time": "1933 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A87277C37FDF2", "submission_order": 1, "result": "WA", "execution_time": "1102 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A87277C37FDF2", "submission_order": 2, "result": "AC", "execution_time": "1463 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8785C1DCE6FA", "submission_order": 1, "result": "AC", "execution_time": "1778 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A88BA1D40CCF1", "submission_order": 1, "result": "AC", "execution_time": "1407 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8BAC3D435F11", "submission_order": 1, "result": "AC", "execution_time": "1972 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8C536D664A0C", "submission_order": 1, "result": "AC", "execution_time": "1177 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8C6928BDA74F", "submission_order": 1, "result": "AC", "execution_time": "1145 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8CD8E4602CB4", "submission_order": 1, "result": "AC", "execution_time": "1477 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8D261C776F19", "submission_order": 1, "result": "WA", "execution_time": "1203 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.h(1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8D261C776F19", "submission_order": 2, "result": "WA", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.h(1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8D261C776F19", "submission_order": 3, "result": "WA", "execution_time": "1438 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8D261C776F19", "submission_order": 4, "result": "AC", "execution_time": "1730 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8DF0F7B905AC", "submission_order": 1, "result": "AC", "execution_time": "1542 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8EA68EC6D2FF", "submission_order": 1, "result": "AC", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A8F66CE5C510E", "submission_order": 1, "result": "AC", "execution_time": "1071 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A92A3FB3050EB", "submission_order": 1, "result": "AC", "execution_time": "1451 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A937FE6ECC95C", "submission_order": 1, "result": "AC", "execution_time": "1486 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A93FD48D95ACA", "submission_order": 1, "result": "AC", "execution_time": "1095 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A952322EF4EB4", "submission_order": 1, "result": "AC", "execution_time": "1476 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A957F2C665D01", "submission_order": 1, "result": "AC", "execution_time": "1137 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A95D1A54ECF7D", "submission_order": 1, "result": "AC", "execution_time": "1356 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A96E7C732CF16", "submission_order": 1, "result": "AC", "execution_time": "1495 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A9879D7BCB028", "submission_order": 1, "result": "AC", "execution_time": "1523 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A9A5EF17F8C41", "submission_order": 1, "result": "AC", "execution_time": "1900 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A9AC854DD30E1", "submission_order": 1, "result": "AC", "execution_time": "1138 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A9E9484246E83", "submission_order": 1, "result": "AC", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n\n    # Step 2: Apply CNOT gate with qubit 0 as control and qubit 1 as target\n    qc.cx(0, 1)\n\n    # Step 3: Apply Pauli-Z gate to the first qubit to introduce the negative phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "A9EC9B09AA829", "submission_order": 1, "result": "AC", "execution_time": "1475 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA20697591080", "submission_order": 1, "result": "RE", "execution_time": "1519 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA20697591080", "submission_order": 2, "result": "AC", "execution_time": "1586 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA2161AB40480", "submission_order": 1, "result": "AC", "execution_time": "1368 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA25589CD0614", "submission_order": 1, "result": "RE", "execution_time": "1536 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cnot(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA25589CD0614", "submission_order": 2, "result": "AC", "execution_time": "1295 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA25C83D6B881", "submission_order": 1, "result": "AC", "execution_time": "1449 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA2C82B6EEBB4", "submission_order": 1, "result": "AC", "execution_time": "2043 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA6AC7CDE5D2D", "submission_order": 1, "result": "WA", "execution_time": "1554 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA6AC7CDE5D2D", "submission_order": 2, "result": "AC", "execution_time": "1540 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AA8403510A71D", "submission_order": 1, "result": "AC", "execution_time": "1113 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AABA024AA14BA", "submission_order": 1, "result": "WA", "execution_time": "1443 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AABA024AA14BA", "submission_order": 2, "result": "AC", "execution_time": "1427 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AACB4F1AD85FC", "submission_order": 1, "result": "WA", "execution_time": "1148 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AACB4F1AD85FC", "submission_order": 2, "result": "WA", "execution_time": "1112 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AACB4F1AD85FC", "submission_order": 3, "result": "AC", "execution_time": "1141 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AACD9462E9B87", "submission_order": 1, "result": "AC", "execution_time": "1349 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1,0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AACFCE71B8C50", "submission_order": 1, "result": "AC", "execution_time": "1632 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AB08554FC6BA0", "submission_order": 1, "result": "AC", "execution_time": "1485 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AB2ECA282CB26", "submission_order": 1, "result": "WA", "execution_time": "1630 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AB2ECA282CB26", "submission_order": 2, "result": "AC", "execution_time": "1523 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AB392E2715280", "submission_order": 1, "result": "AC", "execution_time": "1099 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AB470B61544A7", "submission_order": 1, "result": "AC", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ABA1AA12BA916", "submission_order": 1, "result": "RE", "execution_time": "1406 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ABA1AA12BA916", "submission_order": 2, "result": "WA", "execution_time": "1166 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ABA1AA12BA916", "submission_order": 3, "result": "AC", "execution_time": "1517 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ABB35B3E7EF54", "submission_order": 1, "result": "AC", "execution_time": "1386 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ABDB5071D288F", "submission_order": 1, "result": "AC", "execution_time": "1104 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ABE120836DD00", "submission_order": 1, "result": "AC", "execution_time": "1383 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AC1D15B6A43AE", "submission_order": 1, "result": "AC", "execution_time": "1469 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AC1F77E1DAC42", "submission_order": 1, "result": "AC", "execution_time": "1364 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AC2B394145CC3", "submission_order": 1, "result": "RE", "execution_time": "1127 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cnot(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AC2B394145CC3", "submission_order": 2, "result": "AC", "execution_time": "1342 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AC468F5288EA4", "submission_order": 1, "result": "AC", "execution_time": "1552 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AC9F6B63F56D6", "submission_order": 1, "result": "AC", "execution_time": "1932 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ACA3953E65D31", "submission_order": 1, "result": "AC", "execution_time": "1548 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ACDE51DFE43B1", "submission_order": 1, "result": "AC", "execution_time": "1421 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ACE7C76885CF2", "submission_order": 1, "result": "AC", "execution_time": "1422 ms", "memory": "155 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ACE976CE890F8", "submission_order": 1, "result": "AC", "execution_time": "1117 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ACEAC162AC7F4", "submission_order": 1, "result": "AC", "execution_time": "1227 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD008EFDAF8CC", "submission_order": 1, "result": "AC", "execution_time": "1703 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    \n    qc.cx(control_qubit=0, target_qubit=1)\n    qc.cz(control_qubit=0, target_qubit=1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD2AD824E9BE1", "submission_order": 1, "result": "WA", "execution_time": "1344 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)  # 00 - 10\n    qc.cx(0, 1)  # 00 - 11\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD2AD824E9BE1", "submission_order": 2, "result": "AC", "execution_time": "1351 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)  # 00 + 10\n    qc.cx(0, 1)  # 00 + 11\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD39C79643C1F", "submission_order": 1, "result": "AC", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD4D740AF58D6", "submission_order": 1, "result": "RE", "execution_time": "1473 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(i)\n    qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD4D740AF58D6", "submission_order": 2, "result": "WA", "execution_time": "1451 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD4D740AF58D6", "submission_order": 3, "result": "AC", "execution_time": "1045 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD742A1250D5D", "submission_order": 1, "result": "AC", "execution_time": "1189 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD75299402CA2", "submission_order": 1, "result": "AC", "execution_time": "1424 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD87DA321AF91", "submission_order": 1, "result": "AC", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD93762F93285", "submission_order": 1, "result": "WA", "execution_time": "1475 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD93762F93285", "submission_order": 2, "result": "AC", "execution_time": "1109 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AD9B64631E39F", "submission_order": 1, "result": "AC", "execution_time": "1376 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ADBA2BB110FFC", "submission_order": 1, "result": "AC", "execution_time": "1214 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "ADD49E5307B9B", "submission_order": 1, "result": "AC", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE078366BE7D6", "submission_order": 1, "result": "AC", "execution_time": "1208 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE12121BE4C1A", "submission_order": 1, "result": "AC", "execution_time": "1362 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE13FBFD43860", "submission_order": 1, "result": "AC", "execution_time": "1382 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE3527833EE82", "submission_order": 1, "result": "AC", "execution_time": "1439 ms", "memory": "140 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.ry(-math.pi, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE39EA448E6A4", "submission_order": 1, "result": "AC", "execution_time": "1932 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A2", "user": "AE3FD506878CE", "submission_order": 1, "result": "AC", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n \n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE4ED02BCFEAF", "submission_order": 1, "result": "AC", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gate with control on first qubit and target on second qubit\n    qc.cx(0, 1)\n    \n    # Apply Z gate to the first qubit to introduce the minus sign\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE7481C260FA1", "submission_order": 1, "result": "RE", "execution_time": "1422 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(2 - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE7481C260FA1", "submission_order": 2, "result": "AC", "execution_time": "1047 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(2 - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE826B5336DD3", "submission_order": 1, "result": "AC", "execution_time": "1460 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE932BBB507B9", "submission_order": 1, "result": "AC", "execution_time": "1697 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE9E0DC8F6665", "submission_order": 1, "result": "AC", "execution_time": "1261 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AE9F355318B42", "submission_order": 1, "result": "AC", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AEB6185AA33E6", "submission_order": 1, "result": "AC", "execution_time": "1061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AED1FAE851DE9", "submission_order": 1, "result": "AC", "execution_time": "1132 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AED731D5EA723", "submission_order": 1, "result": "RE", "execution_time": "1880 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    qc.draw(output='mpl')\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF037930C5823", "submission_order": 1, "result": "WA", "execution_time": "1524 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF037930C5823", "submission_order": 2, "result": "AC", "execution_time": "1450 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 1, "result": "RE", "execution_time": "1433 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.rx(2*math.pi,0)\n    qc.rx(2*math.pi,)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 2, "result": "RE", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.rx(2*math.pi,0)\n    qc.rx(2*math.pi,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 3, "result": "WA", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.rx(2*math.pi,0)\n    qc.rx(2*math.pi,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\nfrom qiskit.circuit.library.standard_gates.p import MCPhaseGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.rx(2*math.pi,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 5, "result": "WA", "execution_time": "1197 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    qc.rx(2*math.pi,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 6, "result": "WA", "execution_time": "1432 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x([0,1])\n    qc.rx(2*math.pi,0)\n    qc.rx(2*math.pi,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 7, "result": "WA", "execution_time": "1637 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x([1])\n    qc.rx(2*math.pi,1)\n    qc.x([1])\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 8, "result": "RE", "execution_time": "1302 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x([1])\n    control_rx = rx(2*math.pi,1).control(1)\n    qc.append(control_rx, [0, 1])\n    qc.x([1])\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF1387E66CDC6", "submission_order": 9, "result": "AC", "execution_time": "1116 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF2A0EA1C8067", "submission_order": 1, "result": "AC", "execution_time": "1323 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF7CCB2E54742", "submission_order": 1, "result": "AC", "execution_time": "1818 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    # mcz = ZGate().control(1)\n    # qc.append(mcz, range(2))\n \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF7CCB2E54742", "submission_order": 2, "result": "AC", "execution_time": "1818 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n    # mcz = ZGate().control(1)\n    # qc.append(mcz, range(2))\n \n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AF8C38A093742", "submission_order": 1, "result": "AC", "execution_time": "1633 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFA4AC3C67611", "submission_order": 1, "result": "AC", "execution_time": "1380 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 1, "result": "RE", "execution_time": "1134 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 2, "result": "RE", "execution_time": "1077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 3, "result": "RE", "execution_time": "1549 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 4, "result": "RE", "execution_time": "1499 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 5, "result": "RE", "execution_time": "1626 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 6, "result": "WA", "execution_time": "1080 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 7, "result": "RE", "execution_time": "1536 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 8, "result": "WA", "execution_time": "1054 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFBC9E25AFC5A", "submission_order": 9, "result": "AC", "execution_time": "1209 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFDC5CE0BC517", "submission_order": 1, "result": "AC", "execution_time": "1120 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFE4F06198464", "submission_order": 1, "result": "WA", "execution_time": "1740 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.x(1)\n    qc.h(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFE4F06198464", "submission_order": 2, "result": "WA", "execution_time": "1839 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n    qc.h(0)\n    qc.ch(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFE4F06198464", "submission_order": 3, "result": "WA", "execution_time": "1716 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.x(1)\n    qc.z(1)\n    qc.x(1)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFE4F06198464", "submission_order": 4, "result": "WA", "execution_time": "1724 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.x(1)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFE4F06198464", "submission_order": 5, "result": "AC", "execution_time": "1755 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A2", "user": "AFEE037EEF398", "submission_order": 1, "result": "AC", "execution_time": "1928 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gate with qubit 0 as control and qubit 1 as target\n    qc.cx(0, 1)\n    \n    # Step 3: Apply Z gate to the second qubit to introduce the negative phase\n    qc.z(1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A020B563D22E6", "submission_order": 1, "result": "AC", "execution_time": "1965 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A02F3EB51960F", "submission_order": 1, "result": "WA", "execution_time": "2025 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0, 1)\n    qc.z(0)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A02F3EB51960F", "submission_order": 2, "result": "RE", "execution_time": "1859 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i, i+1)\n    qc.z()\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A02F3EB51960F", "submission_order": 3, "result": "RE", "execution_time": "2070 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i, i + 1)\n    qc.z(0)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A02F3EB51960F", "submission_order": 4, "result": "RE", "execution_time": "1673 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i, i + 1)\n    qc.z(n)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A02F3EB51960F", "submission_order": 5, "result": "RE", "execution_time": "1870 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A02F3EB51960F", "submission_order": 6, "result": "RE", "execution_time": "1853 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0, i)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A02F3EB51960F", "submission_order": 7, "result": "AC", "execution_time": "2182 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A033CC73C4712", "submission_order": 1, "result": "RE", "execution_time": "1461 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(n):\n        qc.cx(i,i+1)\n\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A033CC73C4712", "submission_order": 2, "result": "AC", "execution_time": "2088 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(n-1):\n        qc.cx(i,i+1)\n\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A043F1954D3FF", "submission_order": 1, "result": "AC", "execution_time": "2339 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n      qc.cx(0, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A046247B72E2E", "submission_order": 1, "result": "AC", "execution_time": "2187 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply Hadamard gate to the first qubit to create superposition\n    qc.h(0)\n    \n    # Apply CNOT gates to entangle the first qubit with all other qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Apply Z gate to the first qubit to introduce phase difference\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A0600AF3D2793", "submission_order": 1, "result": "AC", "execution_time": "2082 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i-1, i)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A0811C9BA3A2D", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A08CB804CB43E", "submission_order": 1, "result": "AC", "execution_time": "2081 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0,i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A0AF709FBA6A9", "submission_order": 1, "result": "RE", "execution_time": "1762 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef prepare_state(n):\n    # Step 1: Create a quantum circuit with n qubits\n    qc = QuantumCircuit(n)\n    \n    # Step 2: Apply Hadamard gates to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Step 3: Apply a CNOT gate to entangle the qubits\n    # We will use the first qubit as control and the last qubit as target\n    qc.cx(0, n-1)\n    \n    # Step 4: Apply a phase shift to the last qubit\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A0AF709FBA6A9", "submission_order": 2, "result": "WA", "execution_time": "1965 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n):\n    # Step 1: Create a quantum circuit with n qubits\n    qc = QuantumCircuit(n)\n    \n    # Step 2: Apply Hadamard gates to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Step 3: Apply a CNOT gate to entangle the qubits\n    # We will use the first qubit as control and the last qubit as target\n    qc.cx(0, n-1)\n    \n    # Step 4: Apply a phase shift to the last qubit\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A0AF709FBA6A9", "submission_order": 3, "result": "WA", "execution_time": "2034 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gates to create the |111...1> state\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # The state is now |psi> = (|000...0> - |111...1>)/sqrt(2)\n    # The global phase is ignored, so we don't need to apply any additional phase.\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A0BB41177262F", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+!)\n    \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A0BB41177262F", "submission_order": 2, "result": "AC", "execution_time": "1899 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A0D075D54CD13", "submission_order": 1, "result": "AC", "execution_time": "2089 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1011D265D693", "submission_order": 1, "result": "RE", "execution_time": "1492 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(n):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1011D265D693", "submission_order": 2, "result": "AC", "execution_time": "2173 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1103CB4E748A", "submission_order": 1, "result": "AC", "execution_time": "1943 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A11137E0F9FBA", "submission_order": 1, "result": "RE", "execution_time": "1211 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    qc.cx(0, 3)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A11137E0F9FBA", "submission_order": 2, "result": "RE", "execution_time": "1147 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A131AA29EB05C", "submission_order": 1, "result": "AC", "execution_time": "1887 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    \n    for i in range(n-1):\n      qc.cx(0, i+1)\n    \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A148126C3C74B", "submission_order": 1, "result": "AC", "execution_time": "1804 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1897E3315B9D", "submission_order": 1, "result": "AC", "execution_time": "2258 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(0, n-1):\n        qc.cx(i, i+1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A18A52462EE4D", "submission_order": 1, "result": "WA", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(1)\n    qc.ry(-math.pi, 1)\n    for i in range(n - 1):\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A18A52462EE4D", "submission_order": 2, "result": "WA", "execution_time": "1150 ms", "memory": "140 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(1)\n    qc.ry(-math.pi, 1)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A18A52462EE4D", "submission_order": 3, "result": "AC", "execution_time": "2618 ms", "memory": "143 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-math.pi, 0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 1, "result": "RE", "execution_time": "1216 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n):\n        qc.h(i)\n    qc.cz(0,n-1)\n    qz.x(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 2, "result": "WA", "execution_time": "1186 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n):\n        qc.h(i)\n    qc.cz(0,n-1)\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 3, "result": "WA", "execution_time": "1286 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n):\n        qc.h(i)\n    for i in range(n-1):\n        for j in range(i+1, n):\n            qc.cz(i, j)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 4, "result": "WA", "execution_time": "1144 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n):\n        qc.h(i)\n    for i in range(n-1):\n        qc.cx(i, n-1)\n    qc.z(n-1)\n    for i in range(n-1):\n        qc.cx(i, n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 5, "result": "WA", "execution_time": "1206 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply Pauli-X gate to each qubit to flip the state from |0...0⟩ to |1...1⟩\n    for i in range(n):\n        qc.x(i)\n    \n    # Apply Hadamard gate to each qubit again to create the desired state\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 6, "result": "WA", "execution_time": "1134 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply X gates to all qubits\n    for i in range(n):\n        qc.x(i)\n    \n    # Step 3: Apply a controlled-Z gate\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    \n    # Step 4: Apply X gates again to all qubits\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 7, "result": "WA", "execution_time": "1093 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    # Apply controlled-Z gates to all pairs of qubits\n    for i in range(n-1):\n        for j in range(i+1, n):\n            qc.cz(i, j)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 8, "result": "RE", "execution_time": "1208 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    \n    # Apply a multi-controlled Z gate to introduce the necessary phase\n    if n > 1:\n        qc.h(n-1)\n        qc.mct(list(range(n-1)), n-1)\n        qc.h(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1CE59CD61EF9", "submission_order": 9, "result": "RE", "execution_time": "1117 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):  \n      qc.h(i)  # Apply Hadamard gate to each qubit  \n    qc.x(range(1, n))  # Apply X gate to all qubits except the first one  \n    qc.barrier()  \n    qc.h(0)  # Apply Hadamard gate to the first qubit  \n    qc.cp(math.pi, 0, range(1, n))  # Apply multi-controlled phase gate  \n    qc.h(0)  # Apply Hadamard gate to the first qubit again  \n  \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1F8B2207FBBB", "submission_order": 1, "result": "RE", "execution_time": "1070 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, 4):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1F8B2207FBBB", "submission_order": 2, "result": "AC", "execution_time": "2065 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A1F98C642557D", "submission_order": 1, "result": "AC", "execution_time": "2502 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A22B367D0348F", "submission_order": 1, "result": "AC", "execution_time": "1698 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A242847D583C2", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    circuitEnd = False\n    for i in [int(pow(2, x)) for x in range(0, 4)]:\n\n        for j in range(i):\n            if (j + i >= n):\n                circuitEnd = True\n                break\n            qc.cx(j, j + i)\n        if (circuitEnd):\n            break\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A2502FB1C751E", "submission_order": 1, "result": "AC", "execution_time": "2074 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A27390A57B4AE", "submission_order": 1, "result": "AC", "execution_time": "2076 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A284DBF9AF8B1", "submission_order": 1, "result": "WA", "execution_time": "1247 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n    \n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A284DBF9AF8B1", "submission_order": 2, "result": "WA", "execution_time": "1164 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.x(0)\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A284DBF9AF8B1", "submission_order": 3, "result": "AC", "execution_time": "1911 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A28B97A98E3CF", "submission_order": 1, "result": "AC", "execution_time": "2104 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n - 1):\n        qc.cx(0,i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A296036F604F2", "submission_order": 1, "result": "WA", "execution_time": "1102 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A296036F604F2", "submission_order": 2, "result": "WA", "execution_time": "1506 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        for j in range(i+1, n):\n            qc.cz(i,j)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A2B21B6E2DBDA", "submission_order": 1, "result": "AC", "execution_time": "2082 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # generating ghz state with negative \n    qc.h(0)\n    for i in range(1, n):\n        # entangle the states using cnot with 0 qubit as control\n        qc.cx(0, i)\n    # use z gate to phase flip the highest state\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A2C4B26650747", "submission_order": 1, "result": "AC", "execution_time": "2819 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i-1,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A2DE8B485408C", "submission_order": 1, "result": "AC", "execution_time": "1965 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A2EAFC526ABE8", "submission_order": 1, "result": "AC", "execution_time": "1781 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A2F1E98295CAB", "submission_order": 1, "result": "AC", "execution_time": "1960 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A31BB63869EDF", "submission_order": 1, "result": "AC", "execution_time": "1654 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.cx(0,i)\n    \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A32C82AA11DCE", "submission_order": 1, "result": "AC", "execution_time": "2104 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A33A5B0061BA7", "submission_order": 1, "result": "WA", "execution_time": "1318 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(0,n-1):\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A33A5B0061BA7", "submission_order": 2, "result": "AC", "execution_time": "2263 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(0,n-1):\n        qc.cx(i,i+1)\n    \n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3492770EE3CF", "submission_order": 1, "result": "AC", "execution_time": "2471 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gates from the first qubit to all others\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Apply Z gate to the first qubit to introduce the minus sign\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3821DF0CF4D7", "submission_order": 1, "result": "WA", "execution_time": "1206 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3821DF0CF4D7", "submission_order": 2, "result": "RE", "execution_time": "1178 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3821DF0CF4D7", "submission_order": 3, "result": "AC", "execution_time": "2422 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A38FCE0041B57", "submission_order": 1, "result": "AC", "execution_time": "2246 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, range(1, n))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3939A48C7D4A", "submission_order": 1, "result": "AC", "execution_time": "2248 ms", "memory": "161 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     import random\n#     qc = solve()\n#     sv = Statevector(qc)\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_A3", "user": "A3989E140AB47", "submission_order": 1, "result": "WA", "execution_time": "1095 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(0, n):\n        qc.cx(0, 1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3989E140AB47", "submission_order": 2, "result": "AC", "execution_time": "1951 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(n-1):\n        qc.cx(i, i + 1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3CE6D7691EA9", "submission_order": 1, "result": "AC", "execution_time": "1774 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 1, "result": "WA", "execution_time": "1115 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 2, "result": "WA", "execution_time": "1134 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 3, "result": "RE", "execution_time": "1303 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.cz(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 4, "result": "RE", "execution_time": "1157 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.cz(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 5, "result": "RE", "execution_time": "1185 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.cz(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 6, "result": "WA", "execution_time": "1219 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        \n    for i in range(n-1):\n        qc.cz(i, i+1)\n        \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 7, "result": "WA", "execution_time": "1394 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    \n    for i in range(n-1):\n        qc.cz(i, i+1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n  for i in range(n):\n    qc.x(i)\n    qc.h(i)\n        \n    for i in range(n-1):\n        qc.cz(0, i)\n            \n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 9, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n  for i in range(n):\n    qc.x(i)\n    qc.h(i)\n        \n    for i in range(n):\n        qc.cz(0, i)\n            \n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 10, "result": "WA", "execution_time": "1265 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.x(i)\n      qc.h(i)\n    \n    for i in range(n-1):\n        qc.cz(i, i+1)   \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 11, "result": "WA", "execution_time": "1354 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.x(i)\n    qc.h(i)\n  \n  for i in range(n-1):\n      qc.cz(i, i+1)   \n  \n  return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 12, "result": "WA", "execution_time": "1177 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.x(i)\n    qc.h(i)\n    \n  for i in range(n-1):\n      qc.cz(0, i+1)\n  \n  return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 13, "result": "WA", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.z(i)\n    qc.h(i)\n    \n  for i in range(n-1):\n      qc.cz(0, i+1)\n  \n  return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 14, "result": "WA", "execution_time": "1102 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.z(i)\n    qc.h(i)\n    \n  for i in range(n-1):\n      qc.cz(i, i+1)\n  \n  return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3ED70DB4079E", "submission_order": 15, "result": "AC", "execution_time": "1927 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  qc.x(0)\n  qc.h(0)\n    \n  for i in range(n-1):\n      qc.cx(i, i+1)\n  \n  return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3F7308F7CC04", "submission_order": 1, "result": "RE", "execution_time": "1599 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in n:\n        pc.cx(0,i)\n\n    qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3F7308F7CC04", "submission_order": 2, "result": "RE", "execution_time": "1258 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in n:\n        qc.cx(0,i)\n\n    qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3F7308F7CC04", "submission_order": 3, "result": "RE", "execution_time": "1655 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in n:\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3F7308F7CC04", "submission_order": 4, "result": "RE", "execution_time": "1463 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in n:\n        if i!=0:\n            qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3F7308F7CC04", "submission_order": 5, "result": "RE", "execution_time": "1502 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in n:\n        if i!=0:\n            qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A3F7308F7CC04", "submission_order": 6, "result": "AC", "execution_time": "1814 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n, 1):\n        if i!=0:\n            qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A42066F232F72", "submission_order": 1, "result": "RE", "execution_time": "2859 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    qc.cx(0, 3)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A42066F232F72", "submission_order": 2, "result": "AC", "execution_time": "2107 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A487302D063D7", "submission_order": 1, "result": "RE", "execution_time": "1428 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for a in range(n):\n        qc.cx(0,n+1)\n    qc.crx(2*math.pi,0,1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A487302D063D7", "submission_order": 2, "result": "RE", "execution_time": "1223 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for a in range(1, n):\n        qc.cx(0,n)\n    qc.crx(2*math.pi,0,1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A487302D063D7", "submission_order": 3, "result": "RE", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for a in range(1, n):\n        qc.cx(0,n+1)\n    qc.crx(2*math.pi,0,1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A487302D063D7", "submission_order": 4, "result": "RE", "execution_time": "1442 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for a in range(1, n):\n        qc.cx(0,n)\n    qc.crx(2*math.pi,0,1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A487302D063D7", "submission_order": 5, "result": "AC", "execution_time": "2037 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for a in range(1, n):\n        qc.cx(0,a)\n    qc.crx(2*math.pi,0,1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A4C0DF019DEF2", "submission_order": 1, "result": "RE", "execution_time": "1343 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,range(n))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A4C0DF019DEF2", "submission_order": 2, "result": "AC", "execution_time": "1731 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,range(1,n))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A4D0B66A88E39", "submission_order": 1, "result": "RE", "execution_time": "1542 ms", "memory": "153 MiB", "code": "'''python\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A4D0B66A88E39", "submission_order": 2, "result": "AC", "execution_time": "1711 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A4D5EAB6B0023", "submission_order": 1, "result": "AC", "execution_time": "2138 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A535A988DFA08", "submission_order": 1, "result": "RE", "execution_time": "1118 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(n,n+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A535A988DFA08", "submission_order": 2, "result": "AC", "execution_time": "2228 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A53A1127704A3", "submission_order": 1, "result": "AC", "execution_time": "1701 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A541E59542864", "submission_order": 1, "result": "AC", "execution_time": "2905 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    \n    qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A54CCA61D9025", "submission_order": 1, "result": "AC", "execution_time": "2288 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A57D7932F652A", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    wc.h(0)\n    for i in range(1, n);:\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A57D7932F652A", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n);:\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A57D7932F652A", "submission_order": 3, "result": "RE", "execution_time": "1061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A57D7932F652A", "submission_order": 4, "result": "AC", "execution_time": "1662 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A59FE1CADE361", "submission_order": 1, "result": "WA", "execution_time": "2665 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A59FE1CADE361", "submission_order": 2, "result": "AC", "execution_time": "2789 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5A693494A58B", "submission_order": 1, "result": "AC", "execution_time": "2134 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,range(1,n))\n    qc.cz(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5A76115B9E42", "submission_order": 1, "result": "RE", "execution_time": "1123 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    qc.z(n)\n    for i in range(n):\n        qc.cx(n-i,n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5A76115B9E42", "submission_order": 2, "result": "RE", "execution_time": "1279 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    qc.z(n)\n    for i in range(n):\n        qc.cx(n-i-1,n-i-2)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5A76115B9E42", "submission_order": 3, "result": "RE", "execution_time": "1322 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    qc.z(n)\n    for i in range(n):\n        qc.cx(n-i-1,n-i-2)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5A76115B9E42", "submission_order": 4, "result": "RE", "execution_time": "1197 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    qc.z(n)\n    for i in range(n-1):\n        qc.cx(n-i-1,n-i-2)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5A76115B9E42", "submission_order": 5, "result": "RE", "execution_time": "1081 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    qc.z(n)\n    for i in range(n-1):\n        qc.cx(n-i-1,n-i-2)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5A76115B9E42", "submission_order": 6, "result": "AC", "execution_time": "2370 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.z(n-1)\n    for i in range(n-1):\n        qc.cx(n-i-1,n-i-2)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5B2505DB00DC", "submission_order": 1, "result": "WA", "execution_time": "1332 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    # 1/sqrt(2) * (|000...> + |100...>)\n    for i in range(1,n):\n        qc.cx(0, i)\n    # 1/sqrt(2) * (|000...> + |111...>)\n    for i in range(1,n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5B2505DB00DC", "submission_order": 2, "result": "AC", "execution_time": "2296 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    # 1/sqrt(2) * (|000...> + |100...>)\n    for i in range(1,n):\n        qc.cx(0, i)\n    # 1/sqrt(2) * (|000...> + |111...>)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5E281DE4FFDA", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.h(i)\n    qc.cx(i,i+1)\n    qc.z(i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5E281DE4FFDA", "submission_order": 2, "result": "WA", "execution_time": "1138 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.cx(range(n-1),range(1,n))\n    qc.z(range(n))\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5E281DE4FFDA", "submission_order": 3, "result": "RE", "execution_time": "1095 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.cx(range(n),range(n+1))\n    qc.z(range(n+1))\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5E281DE4FFDA", "submission_order": 4, "result": "RE", "execution_time": "1158 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.cz(range(n),range(n+1))\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5E281DE4FFDA", "submission_order": 5, "result": "RE", "execution_time": "1074 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n-1))\n    qc.cx(range(n-1),range(n))\n    qc.z(range(n))\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5E281DE4FFDA", "submission_order": 6, "result": "RE", "execution_time": "1138 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.cx(range(n-1),range(n))\n    qc.z(range(n))\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5E281DE4FFDA", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.h(i)\n    for j in range(i+1, n):\n        cx(i, j)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A5E281DE4FFDA", "submission_order": 8, "result": "AC", "execution_time": "2014 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6011AB7B5C22", "submission_order": 1, "result": "AC", "execution_time": "2554 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6169A0E80616", "submission_order": 1, "result": "AC", "execution_time": "1783 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n      qc.cx(0, i)\n \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A624B6EDFEEF1", "submission_order": 1, "result": "WA", "execution_time": "1162 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0);\n    qc.h(0);\n    for i in range(1, n-1):\n        qc.cx(0, i);\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A624B6EDFEEF1", "submission_order": 2, "result": "AC", "execution_time": "2324 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0);\n    qc.h(0);\n    for i in range(1, n):\n        qc.cx(0, i);\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A63255A96D0F0", "submission_order": 1, "result": "WA", "execution_time": "1223 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to all qubits to create superposition\n    qc.h(range(n))\n    # Apply Z gate to flip the phase of |1...1⟩\n    qc.z(range(n))\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A63255A96D0F0", "submission_order": 2, "result": "WA", "execution_time": "1524 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply X gates to all qubits\n    for i in range(n):\n        qc.x(i)\n    \n    # Step 3: Apply a multi-controlled Z gate\n    qc.h(n-1)  # Apply Hadamard to the last qubit to transform CZ to multi-controlled Z\n    qc.mcx(list(range(n-1)), n-1)  # Apply the multi-controlled X gate (equivalent to CZ in this context)\n    qc.h(n-1)  # Apply Hadamard again to revert\n    \n    # Step 4: Apply X gates again to all qubits\n    for i in range(n):\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A63255A96D0F0", "submission_order": 3, "result": "AC", "execution_time": "2269 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A63472BB0E1F9", "submission_order": 1, "result": "AC", "execution_time": "1681 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6612BAAB3F55", "submission_order": 1, "result": "WA", "execution_time": "1175 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6612BAAB3F55", "submission_order": 2, "result": "AC", "execution_time": "2188 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A677C117D4DCF", "submission_order": 1, "result": "RE", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n - 1):\n        cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6A439EBFEB57", "submission_order": 1, "result": "AC", "execution_time": "2537 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6B9241AFB198", "submission_order": 1, "result": "RE", "execution_time": "2017 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0,i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6B9241AFB198", "submission_order": 2, "result": "RE", "execution_time": "1998 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0,i)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6B9241AFB198", "submission_order": 3, "result": "RE", "execution_time": "1878 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0,i)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6B9241AFB198", "submission_order": 4, "result": "AC", "execution_time": "2265 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0,i+1)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6CB30F6E0790", "submission_order": 1, "result": "AC", "execution_time": "2118 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0, i)\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6CE727840065", "submission_order": 1, "result": "RE", "execution_time": "1244 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6CE727840065", "submission_order": 2, "result": "AC", "execution_time": "2699 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.cx(0, i)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6DF61E454DFD", "submission_order": 1, "result": "RE", "execution_time": "1147 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6DF61E454DFD", "submission_order": 2, "result": "AC", "execution_time": "1815 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6F5F8B5E2EDA", "submission_order": 1, "result": "AC", "execution_time": "2031 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A6FB159CE921B", "submission_order": 1, "result": "AC", "execution_time": "2078 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0,i+1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A71E21B3BF5F8", "submission_order": 1, "result": "AC", "execution_time": "2025 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        j = (1<<(i.bit_length()-1))\n        qc.cx(i-j,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A749C6F062959", "submission_order": 1, "result": "AC", "execution_time": "1793 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(0,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A74DB5F7D04F3", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n)\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A74DB5F7D04F3", "submission_order": 2, "result": "RE", "execution_time": "1110 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A74DB5F7D04F3", "submission_order": 3, "result": "RE", "execution_time": "1191 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A74DB5F7D04F3", "submission_order": 4, "result": "RE", "execution_time": "1179 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A74DB5F7D04F3", "submission_order": 5, "result": "AC", "execution_time": "2207 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        i+=1\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7693A84F43CC", "submission_order": 1, "result": "AC", "execution_time": "2290 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A79304331F152", "submission_order": 1, "result": "AC", "execution_time": "1715 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7B93D596BD06", "submission_order": 1, "result": "AC", "execution_time": "2257 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(4):\n        for j in range(2**i):\n            if j+2**i<n:\n                qc.cx(j, j+2**i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(7)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A3", "user": "A7BCAFED92981", "submission_order": 1, "result": "AC", "execution_time": "2147 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    \n    for i in range(1,n):\n        qc.cx(control_qubit=0, target_qubit=i)\n    qc.cz(control_qubit=0, target_qubit=1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7BEE6F023B2B", "submission_order": 1, "result": "RE", "execution_time": "1585 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(1,2)\n    qc.cx(2,3)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7BEE6F023B2B", "submission_order": 2, "result": "RE", "execution_time": "1442 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(0)\n\n    qc.cx(0,1)\n    qc.cx(1,2)\n    qc.cx(2,3)\n    \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7BEE6F023B2B", "submission_order": 3, "result": "AC", "execution_time": "2823 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(0)\n\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7CA1EF76C7DE", "submission_order": 1, "result": "WA", "execution_time": "1136 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7CA1EF76C7DE", "submission_order": 2, "result": "AC", "execution_time": "2301 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7CA3B2DC84FA", "submission_order": 1, "result": "AC", "execution_time": "1847 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0) \n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A7FF2AA6B9863", "submission_order": 1, "result": "AC", "execution_time": "2294 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.x(0)\n\tqc.h(0)\n\tfor i in range(1, n):\n\t\tqc.cx(0, i)\n\treturn qc\n'''"}
{"problem": "QPC002_A3", "user": "A815E6BE94D86", "submission_order": 1, "result": "RE", "execution_time": "1759 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0)\n    qc.z(0)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A815E6BE94D86", "submission_order": 2, "result": "RE", "execution_time": "1701 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i)\n    qc.z(0)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A815E6BE94D86", "submission_order": 3, "result": "RE", "execution_time": "1812 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0, i)\n    qc.z(0)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A815E6BE94D86", "submission_order": 4, "result": "AC", "execution_time": "2057 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0, i+1)\n    qc.z(0)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A835D193B30D1", "submission_order": 1, "result": "WA", "execution_time": "1281 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A835D193B30D1", "submission_order": 2, "result": "WA", "execution_time": "1702 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A835D193B30D1", "submission_order": 3, "result": "WA", "execution_time": "1054 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.cx(0,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A835D193B30D1", "submission_order": 4, "result": "RE", "execution_time": "1200 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.c(0,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A85E05D43AB92", "submission_order": 1, "result": "WA", "execution_time": "1118 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-2):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A85E05D43AB92", "submission_order": 2, "result": "RE", "execution_time": "1235 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A85E05D43AB92", "submission_order": 3, "result": "RE", "execution_time": "1120 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A85E05D43AB92", "submission_order": 4, "result": "RE", "execution_time": "1249 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i, i+1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A85E05D43AB92", "submission_order": 5, "result": "AC", "execution_time": "2680 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A86141741B708", "submission_order": 1, "result": "WA", "execution_time": "1406 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,n-1)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A86141741B708", "submission_order": 2, "result": "AC", "execution_time": "2310 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.z(n-1)\n    for i in range(n-1):\n        qc.cx(n-1,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A8622ACF182E2", "submission_order": 1, "result": "AC", "execution_time": "1873 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A87FFF2DF12E8", "submission_order": 1, "result": "AC", "execution_time": "2021 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(n-1): qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A88227E337215", "submission_order": 1, "result": "AC", "execution_time": "2234 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for _ in range(1, n):\n        qc.cx(0,_)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A8AD363BB929B", "submission_order": 1, "result": "AC", "execution_time": "1690 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A8D8889E4E238", "submission_order": 1, "result": "AC", "execution_time": "2331 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A8F6C8DAAE347", "submission_order": 1, "result": "RE", "execution_time": "2362 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    q = QuantumRegister(n,'q')\n    # Write your code here:\n    qc.x(q[0])\n    qc.h(q[0])\n    qc.cx(q[0],range(1, n-1, 1))\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A8FC5B092E9D5", "submission_order": 1, "result": "AC", "execution_time": "2023 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A90FBD9F9B7B9", "submission_order": 1, "result": "AC", "execution_time": "2133 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A93827132DFCE", "submission_order": 1, "result": "AC", "execution_time": "2537 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n#from qiskit.quantum_info import Statevector\n\n\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.cp(np.pi,0,n-1)\n    \n    return qc\n\nqc = solve(4)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_A3", "user": "A93C0831867A8", "submission_order": 1, "result": "AC", "execution_time": "1762 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A946A7CE5F705", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(n):\n        qc.(0,i)\n        \n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A946A7CE5F705", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(1,n):\n        qc.(0,i)\n        \n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A946A7CE5F705", "submission_order": 3, "result": "AC", "execution_time": "2166 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(1,n):\n        qc.cx(0,i)\n        \n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A94916A37EC65", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0,i+1)\n    qc.append(ZGate().control(n-1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A94916A37EC65", "submission_order": 2, "result": "AC", "execution_time": "2505 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0,i+1)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A95F9C65D321B", "submission_order": 1, "result": "AC", "execution_time": "2093 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A972D7F1BDD23", "submission_order": 1, "result": "AC", "execution_time": "2329 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9752B29DE704", "submission_order": 1, "result": "WA", "execution_time": "1610 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9752B29DE704", "submission_order": 2, "result": "AC", "execution_time": "1613 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A98D1D92EBB67", "submission_order": 1, "result": "RE", "execution_time": "1757 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h()\n    qc.cx(0,1)\n    for i in range(n-1):\n        cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A98D1D92EBB67", "submission_order": 2, "result": "WA", "execution_time": "1762 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A98D1D92EBB67", "submission_order": 3, "result": "RE", "execution_time": "1505 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.x(O)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A98D1D92EBB67", "submission_order": 4, "result": "WA", "execution_time": "1702 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A98D1D92EBB67", "submission_order": 5, "result": "AC", "execution_time": "2389 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9914F835BA2D", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n)\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9914F835BA2D", "submission_order": 2, "result": "AC", "execution_time": "1803 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9A1827ACD19C", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)  # 0000 + 1000\n    for i in range(1, n):\n        qc.cx(0, i)\n    # 0000 + 1111\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9DC9F0DB05C1", "submission_order": 1, "result": "WA", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    if n > 2:\n        qc.mcx(list(range(n - 1)), n - 1)\n    else:\n        qc.cz(0, 1)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9DC9F0DB05C1", "submission_order": 2, "result": "WA", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    if n > 1:\n        qc.h(n-1)  # Convert last qubit's Z-basis to X-basis\n        qc.mcx(list(range(n-1)), n-1)  # Apply multi-controlled X (CCX)\n        qc.h(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9EE672FE9DDE", "submission_order": 1, "result": "AC", "execution_time": "1995 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "A9FBBA2C17FEE", "submission_order": 1, "result": "AC", "execution_time": "2106 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AA60E8B9E9C3E", "submission_order": 1, "result": "AC", "execution_time": "1598 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if i==0:\n            continue\n        else:\n            qc.cx(0,i)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AA61D87C20F19", "submission_order": 1, "result": "WA", "execution_time": "1114 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AA61D87C20F19", "submission_order": 2, "result": "AC", "execution_time": "2073 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AAC2C754D9705", "submission_order": 1, "result": "AC", "execution_time": "2240 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AAC328211731E", "submission_order": 1, "result": "WA", "execution_time": "1164 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n        qc.cz(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AAC328211731E", "submission_order": 2, "result": "RE", "execution_time": "1146 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.cz(0,0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AAC328211731E", "submission_order": 3, "result": "AC", "execution_time": "2284 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AAC71AE51B465", "submission_order": 1, "result": "AC", "execution_time": "2092 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AB185ACEEE207", "submission_order": 1, "result": "AC", "execution_time": "1809 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AB1AF90C6C0A5", "submission_order": 1, "result": "RE", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in Range(0, n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AB1AF90C6C0A5", "submission_order": 2, "result": "RE", "execution_time": "1157 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in Range(n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AB1AF90C6C0A5", "submission_order": 3, "result": "AC", "execution_time": "1781 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AB1C2C38E7461", "submission_order": 1, "result": "AC", "execution_time": "2213 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n_bits)\n    qc.h(0)\n    m = 0\n    while 1 << m < n_bits: m += 1\n    for k in range(m):\n        d = 1 << k\n        for i in range(d):\n            if i + d < n_bits: qc.cx(i, i + d)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = get_ghz_circuit(n)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AB3D923244DF2", "submission_order": 1, "result": "WA", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n        qc.cz(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AB3D923244DF2", "submission_order": 2, "result": "AC", "execution_time": "1755 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.cz(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AB9A58131E176", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates between the first qubit and each of the other qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ABB90C05BFB2C", "submission_order": 1, "result": "AC", "execution_time": "1814 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n      qc.cx(0, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ABD3A00E034D8", "submission_order": 1, "result": "AC", "execution_time": "2144 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ABE07DE198530", "submission_order": 1, "result": "RE", "execution_time": "1388 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for _ in range(n):\n        qc.h(0,_)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ABE07DE198530", "submission_order": 2, "result": "RE", "execution_time": "1757 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in range(n):\n        qc.h(0)\n        qc.h(0,_)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ABE07DE198530", "submission_order": 3, "result": "RE", "execution_time": "1410 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for _ in range(n):\n\n        qc.cx(0,_)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ABE07DE198530", "submission_order": 4, "result": "AC", "execution_time": "1957 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for _ in range(1,n):\n        qc.cx(0,_)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC1272236A150", "submission_order": 1, "result": "AC", "execution_time": "2067 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC1CFA08F6B70", "submission_order": 1, "result": "AC", "execution_time": "2191 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC271BDE20F0A", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.visualization import plot_histogram\nfrom qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    # Write your code here:\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC271BDE20F0A", "submission_order": 2, "result": "AC", "execution_time": "2150 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    # Write your code here:\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC48D72C08ACD", "submission_order": 1, "result": "AC", "execution_time": "2116 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i-1, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC5B73F6F4164", "submission_order": 1, "result": "RE", "execution_time": "1296 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    for i in range(n-1):\n        qc.cnot(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC5B73F6F4164", "submission_order": 2, "result": "WA", "execution_time": "1172 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC5B73F6F4164", "submission_order": 3, "result": "WA", "execution_time": "1586 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC5B73F6F4164", "submission_order": 4, "result": "AC", "execution_time": "1809 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC5F22C75BF09", "submission_order": 1, "result": "AC", "execution_time": "2136 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    \n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC60A0CA1AB91", "submission_order": 1, "result": "AC", "execution_time": "2917 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef dnc(qc: QuantumCircuit, l: int, r: int) -> None:\n    if l == r:\n        return\n    m = (l + 1 + r) // 2\n    qc.cx(l, m)\n    dnc(qc, l, m - 1)\n    dnc(qc, m, r)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    qc.h(0)\n    qc.z(0)\n    dnc(qc, 0, n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC6B26FA56F44", "submission_order": 1, "result": "AC", "execution_time": "2550 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n      qc.cx(0, i)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC7686048B2AA", "submission_order": 1, "result": "AC", "execution_time": "2347 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n - 1)\n    qc.z(n - 1)\n\n    for i in range(n - 1):\n        qc.cx(n - 1, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC80AB240920E", "submission_order": 1, "result": "AC", "execution_time": "2585 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AC91BF804DB55", "submission_order": 1, "result": "AC", "execution_time": "2355 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n,1):\n        qc.cx(0,i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ACE5307F90392", "submission_order": 1, "result": "AC", "execution_time": "1792 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    qc.h(0)\n    qc.cx(0, range(1, n))\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AD00C1283EA17", "submission_order": 1, "result": "AC", "execution_time": "1992 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AD1582F526DE6", "submission_order": 1, "result": "WA", "execution_time": "1312 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i, 0)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AD1582F526DE6", "submission_order": 2, "result": "AC", "execution_time": "1970 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(1)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AD18BAD770C7D", "submission_order": 1, "result": "AC", "execution_time": "2201 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(n-1)\n\n    return qc\n\n# if __name__ == \"__main__\":\n#     n=4\n#     qc = solve(n)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A3", "user": "AD1BB3B9F8CA8", "submission_order": 1, "result": "AC", "execution_time": "2235 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  qc.x(0)\n  qc.h(0)\n  for i in range(1, n):\n    qc.cx(0, i)\n  return qc\n'''"}
{"problem": "QPC002_A3", "user": "AD2244DD97E77", "submission_order": 1, "result": "AC", "execution_time": "1919 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AD57570A11ADB", "submission_order": 1, "result": "AC", "execution_time": "2210 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.h(0)\n        return qc\n\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0, i+1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AD5AE7A327B5C", "submission_order": 1, "result": "AC", "execution_time": "1854 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(n-1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AD88CC7A9B594", "submission_order": 1, "result": "AC", "execution_time": "2289 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n, 1):\n        qc.cx(0, i)\n    qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADA6729F04E00", "submission_order": 1, "result": "AC", "execution_time": "1932 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADA691CA9F3D1", "submission_order": 1, "result": "AC", "execution_time": "2134 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADAC2C40FE29A", "submission_order": 1, "result": "WA", "execution_time": "1145 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n-1):\n        \n        qc.cx(0,i+1)\n\n    # qc.cx()\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADAC2C40FE29A", "submission_order": 2, "result": "WA", "execution_time": "1527 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n-1):\n        \n        qc.cx(0,i)\n\n    # qc.cx()\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADAC2C40FE29A", "submission_order": 3, "result": "AC", "execution_time": "2137 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n        \n        qc.cx(0,i)\n\n    # qc.cx()\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADB380C226842", "submission_order": 1, "result": "WA", "execution_time": "1462 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADB380C226842", "submission_order": 2, "result": "AC", "execution_time": "1843 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n      qc.cx(i, i+1)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADD1E436046BE", "submission_order": 1, "result": "AC", "execution_time": "2110 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADD91A8FE7304", "submission_order": 1, "result": "AC", "execution_time": "2547 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.cz(0,n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "ADDECE139295C", "submission_order": 1, "result": "AC", "execution_time": "2123 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    for r in (1, 2, 4, 8):\n        for i in range(r):\n            if i + r < n:\n                qc.cx(i, i + r)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE4597C356D48", "submission_order": 1, "result": "AC", "execution_time": "2107 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n_bits)\n    qc.h(0)\n    m = 0\n    while 1 << m < n_bits: m += 1\n    for k in range(m):\n        d = 1 << k\n        for i in range(d):\n            if i + d < n_bits: qc.cx(i, i + d)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = get_ghz_circuit(n)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE4895FBCFE3D", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for in range n:\n        qc.cx(0,n+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE4895FBCFE3D", "submission_order": 2, "result": "RE", "execution_time": "1277 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,n)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE4895FBCFE3D", "submission_order": 3, "result": "RE", "execution_time": "1277 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,n)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE4895FBCFE3D", "submission_order": 4, "result": "AC", "execution_time": "2134 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE4F4211A31C1", "submission_order": 1, "result": "WA", "execution_time": "1155 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE4F4211A31C1", "submission_order": 2, "result": "WA", "execution_time": "1114 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    for i in range(n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE4F4211A31C1", "submission_order": 3, "result": "AC", "execution_time": "2623 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, range(1, n))\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE58D1D38C435", "submission_order": 1, "result": "WA", "execution_time": "2231 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE58D1D38C435", "submission_order": 2, "result": "AC", "execution_time": "2626 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 1, "result": "WA", "execution_time": "1216 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 2, "result": "RE", "execution_time": "1113 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i,i+1)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 3, "result": "RE", "execution_time": "1516 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i,i+1)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if (i<n):\n        qc.cx(i,i+1)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 5, "result": "RE", "execution_time": "1239 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if (i<n):\n            qc.cx(i,i+1)\n            qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 6, "result": "RE", "execution_time": "1084 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if(i<n):\n            qc.cx(i,i+1)\n            qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 7, "result": "RE", "execution_time": "1194 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if(i<<n):\n            qc.cx(i,i+1)\n            qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 8, "result": "RE", "execution_time": "1704 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if(i!=n):\n            qc.cx(i,i+1)\n            qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 9, "result": "WA", "execution_time": "1106 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.cx(i,i+1)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 10, "result": "WA", "execution_time": "1152 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-2):\n        qc.cx(i,i+1)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i,i+1)\n    qc.(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 12, "result": "RE", "execution_time": "1162 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i,i+1)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7BA7FE03332", "submission_order": 13, "result": "AC", "execution_time": "2142 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE7F9697A0E8E", "submission_order": 1, "result": "AC", "execution_time": "2162 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE93DB4AF3C54", "submission_order": 1, "result": "AC", "execution_time": "2074 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AE997E27BA69F", "submission_order": 1, "result": "AC", "execution_time": "1781 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AEA963A1E4C34", "submission_order": 1, "result": "AC", "execution_time": "2205 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AEA9B672AA849", "submission_order": 1, "result": "AC", "execution_time": "1920 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.cx(0,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AEBB8D3168766", "submission_order": 1, "result": "AC", "execution_time": "2035 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,i)\n\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AED3AE265374C", "submission_order": 1, "result": "RE", "execution_time": "1129 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AED3AE265374C", "submission_order": 2, "result": "AC", "execution_time": "1712 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AEF8547C7E1CA", "submission_order": 1, "result": "AC", "execution_time": "1920 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF13CE2885B3C", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n):\n        if(i == 0):\n            #do nothing\n        qc.cnot(0,n)\n    # Write your code here:\n    qc.draw('mpl')\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF13CE2885B3C", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n):\n        if(i == 0):\n            #do nothing\n        qc.cx([0,n])\n    # Write your code here:\n    qc.draw('mpl')\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF13CE2885B3C", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n):\n        if(i == 0):\n            #do nothing\n        qc.cx([0,n])\n    # Write your code here:\n    qc.draw('mlp')\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF13CE2885B3C", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n):\n        if(i == 0):\n            #do nothing\n        qc.cx([0,n])\n    # Write your code here:\n    #qc.draw('mlp')\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF13CE2885B3C", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    \n    for i in range(n):\n        if(i == 0):\n            #do nothing\n        qc.cx(0,n)\n    qc.z(0)\n    # Write your code here:\n    #qc.draw('mlp')\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF13CE2885B3C", "submission_order": 6, "result": "RE", "execution_time": "1304 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    \n    for i in range(n):\n        #if(i == 0):\n            #do nothing\n        qc.cx(0,n)\n    qc.z(0)\n    # Write your code here:\n    #qc.draw('mlp')\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF243C351D3F8", "submission_order": 1, "result": "AC", "execution_time": "2170 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF2D6255EAF4D", "submission_order": 1, "result": "AC", "execution_time": "1781 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n):\n        if i == 0: continue\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF7DE4128D65D", "submission_order": 1, "result": "WA", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n      qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF7DE4128D65D", "submission_order": 2, "result": "AC", "execution_time": "1895 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n      qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AF8A1A5585737", "submission_order": 1, "result": "AC", "execution_time": "2348 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n      qc.cx(i-1, i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AFA07EB56A204", "submission_order": 1, "result": "WA", "execution_time": "1821 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        for j in range(n):\n            if i<j:\n                qc.cx(i,j)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AFA07EB56A204", "submission_order": 2, "result": "WA", "execution_time": "1635 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        for j in range(n):\n            if i<j:\n                qc.cx(i,j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AFA07EB56A204", "submission_order": 3, "result": "AC", "execution_time": "1932 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if i!=0:\n            qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AFDA29AD1FE5A", "submission_order": 1, "result": "AC", "execution_time": "2170 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,range(1,n))\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AFE80492BAE62", "submission_order": 1, "result": "AC", "execution_time": "2351 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n      qc.cx(0,i+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A3", "user": "AFFE06F2B6977", "submission_order": 1, "result": "AC", "execution_time": "2899 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A02B42334FE90", "submission_order": 1, "result": "DLE", "execution_time": "1557 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A02B42334FE90", "submission_order": 2, "result": "AC", "execution_time": "1566 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n    for i in range(2, n, 2):\n        qc.cx(0, i)\n        if i + 1 <= n-1:\n            qc.cx(1, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A03698AA180B8", "submission_order": 1, "result": "AC", "execution_time": "1699 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.z(0)\n\n    current = [0]\n    nexts = []\n    next = 1\n    while True:            \n        for i in current:\n            for _ in range(2):\n                if next >= n:\n                    return qc\n                qc.cx(i, next)\n                nexts.append(next)\n                next += 1\n        current = nexts\n'''"}
{"problem": "QPC002_A4", "user": "A03FD0C998BBD", "submission_order": 1, "result": "DLE", "execution_time": "1628 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A03FD0C998BBD", "submission_order": 2, "result": "DLE", "execution_time": "1085 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(1, n):\n        qc.cx(i-1, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A042065E5B9C3", "submission_order": 1, "result": "AC", "execution_time": "2304 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, n, 2):\n        qc.cx(0, i)\n        if i+1 <= n-1:\n            qc.cx(1, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A04D3A3F01BA9", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_histogram\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(1,(n+1)//2):\n        if 2*i < n:\n            qc.cx(i,2*i)\n        if 2*i+1 < n:\n            qc.cx(i,2*i+1)\n    # Write your code here:\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A075806C0BA6D", "submission_order": 1, "result": "DLE", "execution_time": "1790 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n      qc.cx(0, i)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A075806C0BA6D", "submission_order": 2, "result": "WA", "execution_time": "1241 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h((0, n-1))\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A07DB94C6A60B", "submission_order": 1, "result": "AC", "execution_time": "2033 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    for r in (1, 2, 4, 8):\n        for i in range(r):\n            if i + r < n:\n                qc.cx(i, i + r)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A08493EE980AD", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #Apply hadamard gate to first qubit\n    qc.h(0)\n\n    #Apply CNOT gate between first and second qubit\n    qc.cx(0,1)\n\n    #Now iterate over pair of qubits starting from index 2\n    for i in range(2,n,2): qc.cx(0,i)if i+1<n: qc.cx(1, i+1)\n\n    #If n is odd apply additional CNOT gate\n    if n%2!=0: qc.cx(0,n-1)\n\n    #Apply Z to first qubits\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A08493EE980AD", "submission_order": 2, "result": "AC", "execution_time": "1911 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #Apply hadamard gate to first qubit\n    qc.h(0)\n\n    #Apply CNOT gate between first and second qubit\n    qc.cx(0,1)\n\n    #Now iterate over pair of qubits starting from index 2\n    for i in range(2,n-1,2): \n        qc.cx(0,i)\n        #if i+1<n:\n        qc.cx(1, i+1)\n\n    #If n is odd apply additional CNOT gate\n    if n%2!=0:\n        qc.cx(0,n-1)\n\n    #Apply Z to first qubits\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A08582D5E3589", "submission_order": 1, "result": "AC", "execution_time": "1881 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(2, n, 2):\n        qc.cx(0, i)\n    for i in range(0, n-1, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A0B637F82B088", "submission_order": 1, "result": "RE", "execution_time": "1091 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    if (n == 3):\n        qc.cx(0,2)\n    elif (n==4):\n        qc.cx(0,2)\n        qc.cx(1,3)\n    elif (n==5):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n    elif (n==6):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n    elif (n==7):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n    elif (n==8):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n    elif (n==9):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n    elif (n==10):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n    elif (n==11):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n    elif (n==12):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n    elif (n==13):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n    elif (n==14):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n        qc.cx(5,13)\n    elif (n==15):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n        qc.cx(5,13)\n        qc.cx(6,14)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A0B637F82B088", "submission_order": 2, "result": "AC", "execution_time": "1799 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    if (n == 3):\n        qc.cx(0,2)\n    elif (n==4):\n        qc.cx(0,2)\n        qc.cx(1,3)\n    elif (n==5):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n    elif (n==6):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n    elif (n==7):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n    elif (n==8):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n    elif (n==9):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n    elif (n==10):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n    elif (n==11):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n    elif (n==12):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n    elif (n==13):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n    elif (n==14):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n        qc.cx(5,13)\n    elif (n==15):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n        qc.cx(5,13)\n        qc.cx(6,14)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A0D4129804F54", "submission_order": 1, "result": "DLE", "execution_time": "1269 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.x(range(n))\n    qc.z(0)\n    qc.x(range(n))\n    target = [i for i in range(n) if i != 0]\n    qc.cx(0,target)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A0D4129804F54", "submission_order": 2, "result": "DLE", "execution_time": "1414 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    target = [i for i in range(n) if i != 0]\n    qc.cx(0,target)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A0D4129804F54", "submission_order": 3, "result": "AC", "execution_time": "2217 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, n - 1)\n    target_l = [i for i in range(n // 2) if i != 0]\n    target_r = [n - 2 - i for i in range((n - 1) // 2) if i != n - 1]\n    print(target_l)\n    print(target_r)\n    for target in target_l:\n        qc.cx(0, target)\n    for target in target_r:\n        qc.cx(n - 1, target)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A0D9C14CAFAD2", "submission_order": 1, "result": "AC", "execution_time": "2666 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n\n    i = 1\n    while i < n:\n        for j in range(i):\n            if i + j < n:\n                qc.cx(j, i + j)\n        i *= 2\n    \n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A0D9C14CAFAD2", "submission_order": 2, "result": "AC", "execution_time": "2666 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n\n    i = 1\n    while i < n:\n        for j in range(i):\n            if i + j < n:\n                qc.cx(j, i + j)\n        i *= 2\n    \n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A0F3CF7EC4123", "submission_order": 1, "result": "AC", "execution_time": "2397 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef dnc(qc: QuantumCircuit, l: int, r: int) -> None:\n    if l == r:\n        return\n    m = (l + 1 + r) // 2\n    qc.cx(l, m)\n    dnc(qc, l, m - 1)\n    dnc(qc, m, r)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    qc.h(0)\n    qc.z(0)\n    dnc(qc, 0, n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A11A7511E2BC6", "submission_order": 1, "result": "AC", "execution_time": "2134 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    hi = 1\n    while hi < n:\n        k = hi\n        for i in range(k):\n            if hi == n:\n                break\n            qc.cx(i, k+i)\n            hi += 1\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A15068ADD7140", "submission_order": 1, "result": "DLE", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A15068ADD7140", "submission_order": 2, "result": "AC", "execution_time": "2316 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i//2,i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A15857D819D31", "submission_order": 1, "result": "AC", "execution_time": "2164 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx((i + 1) // 2 - 1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A16B7667B9D32", "submission_order": 1, "result": "DLE", "execution_time": "1348 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n      qc.cx(i-1, i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A16B7667B9D32", "submission_order": 2, "result": "WA", "execution_time": "1314 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,n-1)\n    if n%2 == 0:\n      for i in range(1, n//2):\n        qc.cx(0,i)\n        qc.cx(n-1,n-1-i)\n    else:\n      qc.cx(0,n//2)\n      for i in range(1, n//2):\n        qc.cx(0,i)\n        qc.cx(n-1,n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A16B7667B9D32", "submission_order": 3, "result": "AC", "execution_time": "1990 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,n-1)\n    if n%2 == 0:\n      for i in range(1, n//2):\n        qc.cx(0,i)\n        qc.cx(n-1,n-1-i)\n    else:\n      qc.cx(0,n//2)\n      for i in range(1, n//2):\n        qc.cx(0,i)\n        qc.cx(n-1,n-1-i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A1C3DF706512E", "submission_order": 1, "result": "AC", "execution_time": "1958 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n):\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        if i%2:\n            qc.cx(0,i)\n        else:\n            qc.cx(1,i)\n    \n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A21804371D447", "submission_order": 1, "result": "RE", "execution_time": "1771 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    assert 2<n<15,'value of n is larger'\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    \n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A21804371D447", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuite.library import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    assert 2<n<15,'value of n is larger'\n    qc.h(0)\n    for i in range(n):\n        qc.h(i)\n    \n    qc.append(MCXGate(n-1), list(range(n)))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A21804371D447", "submission_order": 3, "result": "RE", "execution_time": "1468 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    assert 2<n<15,'value of n is larger'\n\n    for i in range(n):\n        qc.h(i)\n    \n    qc.cz(0,1)\n    qc.cz(1,2)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A21804371D447", "submission_order": 4, "result": "RE", "execution_time": "1553 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    qc.cz(0,1)\n    qc.cz(1,2)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A21804371D447", "submission_order": 5, "result": "WA", "execution_time": "1297 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    \n    qc.z(0)\n    \n    for i in range(1,n):\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A21804371D447", "submission_order": 6, "result": "WA", "execution_time": "1329 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.x(i)\n    \n    qc.z(0)\n    \n    for i in range(1,n):\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A246D967CBB12", "submission_order": 1, "result": "WA", "execution_time": "1132 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        if i * i > n:\n            break\n        qc.cx(0, i)\n    \n    for j in range(i, n, i):\n        for offset in range(0, i):\n            if j + offset >= n:\n                break\n            qc.cx(offset, j + offset)\n    return qc\n    \n    qc.append(HGate().inverse(), [0])\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A246D967CBB12", "submission_order": 2, "result": "AC", "execution_time": "1882 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    if n == 2:\n        qc.cx(0, 1)\n        qc.z(0)\n        return qc\n    for i in range(1, n):\n        if i * i > n:\n            break\n        qc.cx(0, i)\n    \n    for j in range(i, n, i):\n        for offset in range(0, i):\n            if j + offset >= n:\n                break\n            qc.cx(offset, j + offset)\n    qc.z(0)\n    return qc\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A276337843B71", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)  # 0000 + 1000\n    for i in range(1, n):\n        j = 0\n        while 2 ** j <= i:\n            j *= 2\n        assert j >= 1\n        j -= 1\n        i2 = i - 2 ** j\n        qc.cx(i2, i)\n    # 0000 + 1111\n    qc.z(0)  # 0000 - 1111\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A276337843B71", "submission_order": 2, "result": "AC", "execution_time": "1926 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)  # 0000 + 1000\n    for i in range(1, n):\n        j = 0\n        while 2 ** j <= i:\n            j += 1\n        assert j >= 1\n        j -= 1\n        assert 2 ** j <= i\n        i2 = i - 2 ** j\n        qc.cx(i2, i)\n    # 0000 + 111\n    qc.z(0)  # 0000 - 1111\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A278A46FE1A11", "submission_order": 1, "result": "DLE", "execution_time": "1129 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A278A46FE1A11", "submission_order": 2, "result": "RE", "execution_time": "1374 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    s=1\n    while s<n:\n        for i in range(0,n-s,2*s):\n            qc.cx(i,i+s)\n            s*=2\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A278A46FE1A11", "submission_order": 3, "result": "RE", "execution_time": "1053 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.h(i-1,i)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A278A46FE1A11", "submission_order": 4, "result": "RE", "execution_time": "1123 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.h(i-1,i)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A299AB2C54C54", "submission_order": 1, "result": "AC", "execution_time": "2405 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(4):\n        for j in range(2**i):\n            if j+2**i<n:\n                qc.cx(j, j+2**i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(7)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A4", "user": "A2B89859C85F5", "submission_order": 1, "result": "DLE", "execution_time": "1230 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n, 1):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2B89859C85F5", "submission_order": 2, "result": "RE", "execution_time": "1482 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.mcx(0, [i for i in range(1, n, 1)])\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2B89859C85F5", "submission_order": 3, "result": "RE", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        if c % 2 == 0:\n            if (i + 1) < n:\n                qc.cx(i, i + 1)\n            if (i + 2) < n:\n                qc.cx(i, i + 2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2B89859C85F5", "submission_order": 4, "result": "DLE", "execution_time": "1237 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        if i % 2 == 0:\n            if (i + 1) < n:\n                qc.cx(i, i + 1)\n            if (i + 2) < n:\n                qc.cx(i, i + 2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2B89859C85F5", "submission_order": 5, "result": "AC", "execution_time": "2082 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n-1)\n    for i in range(n//2-1):\n        qc.cx(i, i+1)\n    for i in range(n//2-1):\n        qc.cx(n-1-i, n-1-i-1)\n    if n%2:\n        qc.cx(n//2-1, n//2)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2EB5DC0FE2A7", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom collections import deque\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    ok = [0,]\n    ng = deque()\n    for i in range(1,n):\n        ng.append(i)\n    \n    while ng:\n        length=len(ok)\n        for i in range(ok):\n            if not ng:\n                break\n            j=ng.popleft()\n            qc.cx(i,j)\n            ok.append(i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2EB5DC0FE2A7", "submission_order": 2, "result": "RE", "execution_time": "1292 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    ok_cnt=1\n    nxt=1\n    \n    while ng!=n:\n        for i in range(ok_cnt):\n            if nxt==n:\n                break\n            qc.cx(i,nxt)\n            nxt+=1\n            ok_cnt+=1\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2EB5DC0FE2A7", "submission_order": 3, "result": "RE", "execution_time": "1174 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    ok_cnt=1\n    nxt=1\n    \n    while ng!=n:\n        tmp=0\n        for i in range(ok_cnt):\n            if nxt==n:\n                break\n            qc.cx(i,nxt)\n            nxt+=1\n            tmp+=1\n        ok_cnt+=tmp\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2EB5DC0FE2A7", "submission_order": 4, "result": "AC", "execution_time": "1904 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    ok_cnt=1\n    nxt=1\n    \n    while nxt!=n:\n        tmp=0\n        for i in range(ok_cnt):\n            if nxt==n:\n                break\n            qc.cx(i,nxt)\n            nxt+=1\n            tmp+=1\n        ok_cnt+=tmp\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A2FCEBC0885D1", "submission_order": 1, "result": "AC", "execution_time": "1802 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tmp = 0\n    lim = 1\n    for i in range(1,n):\n        qc.cx(tmp,i)\n        tmp += 1\n        if tmp == lim:\n            lim *= 2\n            tmp = 0\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A30C18B9911BD", "submission_order": 1, "result": "DLE", "execution_time": "1205 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A30C18B9911BD", "submission_order": 2, "result": "RE", "execution_time": "1273 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(i/2, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A30C18B9911BD", "submission_order": 3, "result": "AC", "execution_time": "2071 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(i//2, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A32CBC4CD7E84", "submission_order": 1, "result": "DLE", "execution_time": "1760 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if i!=0:\n            qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A32CBC4CD7E84", "submission_order": 2, "result": "RE", "execution_time": "2109 ms", "memory": "147 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        if i%2==0:\n            qc.cx(i,i)\n        else:\n            qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A32CBC4CD7E84", "submission_order": 3, "result": "AC", "execution_time": "1895 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        if i%2==0:\n            qc.cx(1,i)\n        else:\n            qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A3402602FAA4C", "submission_order": 1, "result": "WA", "execution_time": "2702 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(1,n // 2):\n        qc.cx(0,2 * i)\n        qc.cx(1,2 * i + 1)\n        if n % 2 == 1:\n            qc.cx(0,n - 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A3402602FAA4C", "submission_order": 2, "result": "AC", "execution_time": "2243 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(1,n // 2):\n        qc.cx(0,2 * i)\n        qc.cx(1,2 * i + 1)\n    if n % 2 == 1:\n        qc.cx(0,n - 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A348B6FBC1C69", "submission_order": 1, "result": "WA", "execution_time": "2013 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, (n + 1)//2):\n        qc.cx(0, i)\n    for j in range((n + 1)//2, n):\n        qc.cx(j - (n+1)//2, j)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A348B6FBC1C69", "submission_order": 2, "result": "AC", "execution_time": "2173 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, (n + 1)//2):\n        qc.cx(0, i)\n    for j in range((n + 1)//2, n):\n        qc.cx(j - (n+1)//2, j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A364B9BE612CE", "submission_order": 1, "result": "AC", "execution_time": "2259 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    qc0 = QuantumCircuit(n-1)\n    for i in range(n-1):\n        qc0.x(i)\n    cxgates = qc0.to_gate().control(1)\n\n    qc.append(cxgates, range(n))\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A36518D5A8D75", "submission_order": 1, "result": "WA", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    \n    if n == 2:\n        qc.cz(0, 1)\n    else:\n        qc.h(n-1) \n        qc.mcx(list(range(n-1)), n-1) \n        qc.h(n-1) \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A38153CFF44EC", "submission_order": 1, "result": "DLE", "execution_time": "1163 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0,i+1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A391E87457BC1", "submission_order": 1, "result": "DLE", "execution_time": "1471 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    \n    for i in range(n-1):\n      qc.cx(0, i+1)\n    \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A391E87457BC1", "submission_order": 2, "result": "AC", "execution_time": "2290 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    \n    step = 1\n    while step < n:\n\n        for i in range(step):\n            if step + i < n:\n                qc.cx(i, step + i)\n            else:\n                break\n\n        step *= 2\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A456F813F38D7", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.z(n-)\n    for i in range(n-1):\n        qc.cx(n-i-1,n-i-2)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A456F813F38D7", "submission_order": 2, "result": "DLE", "execution_time": "1378 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.z(n-1)\n    for i in range(n-1):\n        qc.cx(n-i-1,n-i-2)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A47C938F67E74", "submission_order": 1, "result": "WA", "execution_time": "1338 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mid = n // 2\n    qc.x(mid)\n    qc.h(mid)\n    \n    for i in range(mid + 1, n):\n        qc.cx(mid, i)\n    for i in range(mid - 1):\n        qc.cx(mid, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A47C938F67E74", "submission_order": 2, "result": "DLE", "execution_time": "1442 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # mid = n // 2\n    # qc.x(mid)\n    # qc.h(mid)\n    \n    # for i in range(mid + 1, n):\n    #     qc.cx(mid, i)\n    # for i in range(mid - 1):\n    #     qc.cx(mid, i)\n\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A47C938F67E74", "submission_order": 3, "result": "DLE", "execution_time": "1225 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # mid = n // 2\n    # qc.x(mid)\n    # qc.h(mid)\n    \n    # for i in range(mid + 1, n):\n    #     qc.cx(mid, i)\n    # for i in range(mid - 1):\n    #     qc.cx(mid, i)\n\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A47C938F67E74", "submission_order": 4, "result": "AC", "execution_time": "2079 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    \n    for m in range(n):\n        for k in range(2 ** m):\n            if ((2 ** m) + k) >= n: break\n            qc.cx(k, 2 ** m + k)\n        \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A48D8A892B32D", "submission_order": 1, "result": "RE", "execution_time": "1141 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    l = int(math.ceil(math.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A48D8A892B32D", "submission_order": 2, "result": "WA", "execution_time": "1242 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    l = int(math.ceil(math.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n\n    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A48D8A892B32D", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    l = int(math.ceil(math.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A491559766596", "submission_order": 1, "result": "AC", "execution_time": "2294 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    controls = [0, 0, 1, 0, 1, 2, 3, 0, 1, 2, 3, 4, 5, 6, 7,]\n\n    for i in range(1, n):\n        qc.cx(controls[i - 1], i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A49741052A04A", "submission_order": 1, "result": "AC", "execution_time": "2243 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    if n < 6:\n        for i in range(1, n):\n            qc.cx(0, i)\n    else:\n         for i in range(1, 5):\n             qc.cx(0, i)\n         if n < 9:\n             for i in range(5, n):\n                 qc.cx(1, i)\n         else:\n             for i in range(5, 8):\n                 qc.cx(1, i)\n             if n < 11:\n                 for i in range(8, n):\n                     qc.cx(2, i)\n             else:\n                 for i in range(8, 10):\n                     qc.cx(2, i)\n                 if n > 10:\n                     qc.cx(5, 10)\n                 if n > 11:\n                     qc.cx(5, 11)\n                 if n > 12:\n                     qc.cx(3, 12)\n                 if n > 13:\n                     qc.cx(6, 13)\n                 if n > 14:\n                     qc.cx(8, 14)\n                 if n > 15:\n                     qc.cx(10, 15)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A4997764F5593", "submission_order": 1, "result": "AC", "execution_time": "2077 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    now = 1\n    while now<=n-1:\n        for i in range(now):\n            if now+i+1>=n:\n                break\n            qc.cx(i+1,i+1+now)\n        now *= 2\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A4CAF3458F829", "submission_order": 1, "result": "DLE", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A4CAF3458F829", "submission_order": 2, "result": "AC", "execution_time": "2258 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        j=i\n        for k in reversed(range(60)):\n            if (1<<k)&i:\n                j^=1<<k\n                break\n        qc.cx(j,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A4D40D79EDCA4", "submission_order": 1, "result": "AC", "execution_time": "1873 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    is_odd = n % 2\n    \n    mid = n//2\n    rang = n//2\n    if not is_odd:\n        mid -= 1\n        rang -= 1\n    qc.h(mid)\n    qc.z(mid)\n    for i in range(rang):\n        qc.cx(mid + i, mid + i + 1)\n        qc.cx(mid -i, mid - i - 1)\n    if not is_odd:\n        qc.cx(n-2, n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A500091EAA764", "submission_order": 1, "result": "AC", "execution_time": "1806 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for _ in range(1,n // 2):\n        qc.cx(0,_ * 2)\n        qc.cx(1,_ * 2 + 1)\n    if n % 2 == 1:\n        qc.cx(0,n - 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A512CB8E0E5FC", "submission_order": 1, "result": "WA", "execution_time": "1138 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n):\n        if i % 2 == 0:\n            if i != 0:\n                qc.x(i)\n            if i != n - 1:\n                qc.cx(i, i + 1)\n    for i in range(n):\n        if i % 2 == 1:\n            if i != n - 1:\n                qc.x(i)\n                qc.cx(i, i + 1)\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A512CB8E0E5FC", "submission_order": 2, "result": "AC", "execution_time": "2483 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    max_qubit = 1\n    for i in range(4):\n        for j in range(2 ** i):\n            qc.cx(j, j + 2 ** i)\n            max_qubit = max(j + 2 ** i, max_qubit)\n            if max_qubit == n - 1:\n                break\n        if max_qubit == n - 1:\n            break\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A515628DEC42F", "submission_order": 1, "result": "AC", "execution_time": "1654 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n      qc.cx(int(i/2), i)\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A51B9FBCD736E", "submission_order": 1, "result": "AC", "execution_time": "1958 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n_bits)\n    qc.h(0)\n    m = 0\n    while 1 << m < n_bits: m += 1\n    for k in range(m):\n        d = 1 << k\n        for i in range(d):\n            if i + d < n_bits: qc.cx(i, i + d)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = get_ghz_circuit(n)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A55207EECD40F", "submission_order": 1, "result": "AC", "execution_time": "1732 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    qc.cx(0,1)\n    if n>2:\n        ent_num=1\n        ent_num_tmp=1\n        while(True):\n            for i in range(ent_num+1):\n                qc.cx(i, ent_num+1+i)\n                ent_num_tmp+=1\n\n                if ent_num+i+1==n-1:\n                    break\n            else:\n                ent_num=ent_num_tmp\n                continue\n            break\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A56D21B9A9767", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom collections import deque\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    kouho = deque([])\n    for i in range(n-1):\n        target = i + 1\n        if kouho:\n            a = kouho.popleft()\n            qc.cx(a, target)\n        else:\n            qc.cx(0, target)\n            for j in range(1, target):\n                kouho.append(j)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A56D21B9A9767", "submission_order": 2, "result": "AC", "execution_time": "1774 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    kouho = []\n    for i in range(n-1):\n        target = i + 1\n        if kouho:\n            a = kouho.pop()\n            qc.cx(a, target)\n        else:\n            qc.cx(0, target)\n            for j in range(1, target):\n                kouho.append(j)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5735DE8866E6", "submission_order": 1, "result": "WA", "execution_time": "1301 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mid = n//2\n    qc.h(mid)\n    qc.x(mid)\n    for i in range(mid)[::-1]:\n        qc.cx(i,i+1)\n    for i in range(mid, n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5735DE8866E6", "submission_order": 2, "result": "AC", "execution_time": "1994 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mid = n//2\n    qc.x(mid)\n    qc.h(mid)\n    for i in range(mid)[::-1]:\n        qc.cx(i+1,i)\n    for i in range(mid, n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A576C32D73DAF", "submission_order": 1, "result": "DLE", "execution_time": "1081 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A576C32D73DAF", "submission_order": 2, "result": "DLE", "execution_time": "1173 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A579EB1F8A247", "submission_order": 1, "result": "AC", "execution_time": "2598 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0) \n    qc.h(0)\n    l = int(np.ceil(np.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A59F662A5B605", "submission_order": 1, "result": "DLE", "execution_time": "1256 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n      qc.cx(0, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A59F662A5B605", "submission_order": 2, "result": "AC", "execution_time": "1822 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, n-1)\n    for i in range(n//2):\n      if n%2 == 0:\n        if i != n//2-1:\n          qc.cx(0, i+1)\n          qc.cx(n-1, n-i-2)\n      else:\n        qc.cx(0, i+1)\n        if i != n//2-1:\n          qc.cx(n-1, n-i-2)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5ACBA3D1748E", "submission_order": 1, "result": "RE", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    l = int(np.ceil(np.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5ACBA3D1748E", "submission_order": 2, "result": "AC", "execution_time": "2449 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    l = int(np.ceil(np.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5DA0DA8C95CC", "submission_order": 1, "result": "AC", "execution_time": "1768 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    for i in range(2,n-1,2):\n        qc.cx(0,i)\n        qc.cx(i,i+1)\n    \n    if n%2!=0:\n        qc.cx(0,n-1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5ED97528AF41", "submission_order": 1, "result": "DLE", "execution_time": "1536 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n, 2):\n        qc.cx(0, i)\n\n    # 2回目の並列CNOT\n    for i in range(2, n, 2):\n        qc.cx(0, i)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5ED97528AF41", "submission_order": 2, "result": "RE", "execution_time": "1126 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    def entangle(idx1, idx2):\n        if idx2 > n - 1:\n            return\n        qc.cnot(idx1, idx2)\n        entangle(idx2, (idx2 + 1) * 2 - 1)\n        entangle(idx2, (idx2 + 1) * 2)\n    entangle(0, 1)\n    entangle(0, 2)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5ED97528AF41", "submission_order": 3, "result": "WA", "execution_time": "1067 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    def entangle(idx1, idx2):\n        if idx2 > n - 1:\n            return\n        qc.cx(idx1, idx2)\n        entangle(idx2, (idx2 + 1) * 2 - 1)\n        entangle(idx2, (idx2 + 1) * 2)\n    entangle(0, 1)\n    entangle(0, 2)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A5ED97528AF41", "submission_order": 4, "result": "AC", "execution_time": "1833 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    def entangle(idx1, idx2):\n        if idx2 > n - 1:\n            return\n        qc.cx(idx1, idx2)\n        entangle(idx2, (idx2 + 1) * 2 - 1)\n        entangle(idx2, (idx2 + 1) * 2)\n    entangle(0, 1)\n    entangle(0, 2)\n    qc.z(n- 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A60CB7080B75D", "submission_order": 1, "result": "RE", "execution_time": "1608 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    targets = range(1, n)\n    qc.append(MCXGate(len(targets)), [0] + list(targets))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A60CB7080B75D", "submission_order": 2, "result": "WA", "execution_time": "1510 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cz(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A60CB7080B75D", "submission_order": 3, "result": "DLE", "execution_time": "1107 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A62B7D5E54CC8", "submission_order": 1, "result": "AC", "execution_time": "2433 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i//2,i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 1, "result": "DLE", "execution_time": "1152 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 2, "result": "WA", "execution_time": "1541 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if(n <= 10):\n        qc.h(0)\n        for i in range(n - 1):\n            qc.cx(i, i + 1)\n        qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 3, "result": "WA", "execution_time": "1153 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if(n <= 8):\n        qc.h(0)\n        for i in range(n - 1):\n            qc.cx(i, i + 1)\n        qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 4, "result": "WA", "execution_time": "1420 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if(n > 8):\n        n = 8\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 5, "result": "WA", "execution_time": "1184 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if(n > 8):\n        n = 8\n    qc.h(0)\n    max_n = min(n, 9)\n    for i in range(max_n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 6, "result": "WA", "execution_time": "1740 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    max_n = min(n, 9)\n    for i in range(max_n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 7, "result": "WA", "execution_time": "1768 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    max_n = min(n, 9)\n    for i in range(max_n - 1):\n        qc.cx(i, i + 1)\n    qc.z(max_n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 8, "result": "WA", "execution_time": "1131 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cz(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 9, "result": "DLE", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 10, "result": "WA", "execution_time": "1743 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n <= 10):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    elif (n > 10):\n      for i in range(n - 7, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 7):\n        qc.cx(i + 1, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 11, "result": "WA", "execution_time": "1127 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n <= 10):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    elif (n > 10):\n      for i in range(n - 7, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 7):\n        qc.cx(i + 1, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 12, "result": "WA", "execution_time": "1374 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n < 10):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    elif (n >= 10):\n      for i in range(n - 7, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 7):\n        qc.cx(i + 1, i)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 13, "result": "WA", "execution_time": "1520 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n < 9):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    else:\n      for i in range(n - 7, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 7):\n        qc.cx(i + 1, i)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 14, "result": "WA", "execution_time": "1474 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n < 9):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    else:\n      for i in range(n - 8, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 8):\n        qc.cx(i + 1, i)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 15, "result": "WA", "execution_time": "1254 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n < 9):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    else:\n      for i in range(n - 8, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 8):\n        qc.cx(i + 1, i)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 16, "result": "WA", "execution_time": "1795 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n < 9):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    else:\n      for i in range(n - 8, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 8):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 17, "result": "WA", "execution_time": "2087 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n < 10):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    else:\n      for i in range(n - 6, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 6):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 18, "result": "WA", "execution_time": "1302 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if (n < 5):\n      for i in range(n - 1):\n        qc.cx(i, i + 1)\n    else:\n      for i in range(n - 8, n - 1):\n        qc.cx(i , i + 1)\n      for i in range(n - 8):\n        qc.cx(i, i + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A67B2CC3ADFB7", "submission_order": 19, "result": "AC", "execution_time": "1980 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    end = 1\n    while end < n:\n        for left in range(end):\n            qc.cx(left, end)\n            end += 1\n            if end == n:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A688686540BF7", "submission_order": 1, "result": "DLE", "execution_time": "1375 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, range(1, n))\n    qc.cz(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A688686540BF7", "submission_order": 2, "result": "WA", "execution_time": "1131 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        if not (n >> i) & 1:\n            continue\n        qc.cx(0, i)\n    qc.cz(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A688686540BF7", "submission_order": 3, "result": "WA", "execution_time": "1543 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.x(range(1, n))\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A688686540BF7", "submission_order": 4, "result": "DLE", "execution_time": "1414 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, range(1, n))\n    qc.cz(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A69A63194421F", "submission_order": 1, "result": "RE", "execution_time": "1206 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    cnt = 0\n    now = [0]\n    flag = True\n    while flag:\n        nxt = now[:]\n        for i in now:\n            if i+2**cnt == n:\n                flag = false\n                break\n            qc.cx(i,i+2**cnt)\n            nxt.append(i+2**cnt)\n        cnt += 1\n        now = nxt\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A69A63194421F", "submission_order": 2, "result": "AC", "execution_time": "1786 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\na = [[0, 1], [0, 2], [1, 3], [0, 4], [1, 5], [2, 6], [3, 7], [0, 8], [1, 9], [2, 10], [3, 11], [4, 12], [5, 13], [6, 14]]\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(a[i][0],a[i][1])\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6A04F610E5B2", "submission_order": 1, "result": "AC", "execution_time": "1854 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n):\n        if i*2+1<n:\n            qc.cx(i,i*2+1)\n            if i*2+2<n:\n                qc.cx(i,i*2+2)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6A7A6FC1B07B", "submission_order": 1, "result": "WA", "execution_time": "1166 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    if n > 1:\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6A7A6FC1B07B", "submission_order": 2, "result": "WA", "execution_time": "1087 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply X gate to all qubits to flip them\n    for i in range(n):\n        qc.x(i)\n    \n    # Apply controlled-Z gate between the first qubit and all other qubits\n    for i in range(1, n):\n        qc.cz(0, i)\n    \n    # Apply X gate again to all qubits to flip them back\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6EDFF2AFBC97", "submission_order": 1, "result": "DLE", "execution_time": "1160 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6EDFF2AFBC97", "submission_order": 2, "result": "DLE", "execution_time": "1130 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6EDFF2AFBC97", "submission_order": 3, "result": "WA", "execution_time": "1469 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    qc.cx(0, n-1)\n\n    # Mitad superior del circuito: qubit 0 hasta qubit n/2-1 controla a los siguientes\n    for i in range(0, n//2):\n        qc.cx(i, i+1)\n    \n    # Mitad inferior del circuito: qubit n-1 hasta qubit n/2 controla a los anteriores\n    for i in range(n-1, n//2+1, -1):\n        qc.cx(i, i-1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6EDFF2AFBC97", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n        qc.h(0)\n\n    if n > 1:\n      \n      qc.cx(0, n-1)\n\n      # Mitad superior del circuito: qubit 0 hasta qubit n/2-1 controla a los siguientes\n      for i in range(0, n//2):\n          qc.cx(i, i+1)\n      \n      # Mitad inferior del circuito: qubit n-1 hasta qubit n/2 controla a los anteriores\n      for i in range(n-1, n//2+1, -1):\n          qc.cx(i, i-1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6EDFF2AFBC97", "submission_order": 5, "result": "WA", "execution_time": "1951 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    if n > 1:\n      \n      qc.cx(0, n-1)\n\n      # Mitad superior del circuito: qubit 0 hasta qubit n/2-1 controla a los siguientes\n      for i in range(0, n//2):\n          qc.cx(i, i+1)\n      \n      # Mitad inferior del circuito: qubit n-1 hasta qubit n/2 controla a los anteriores\n      for i in range(n-1, n//2+1, -1):\n          qc.cx(i, i-1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6EDFF2AFBC97", "submission_order": 6, "result": "WA", "execution_time": "1546 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    if n > 1:\n      \n        qc.cx(0, n-1)\n\n        for i in range(0, n//2):\n            qc.cx(i, i+1)\n      \n        if n > 2:\n            for i in range(n-1, n//2+1, -1):\n                qc.cx(i, i-1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A6EDFF2AFBC97", "submission_order": 7, "result": "AC", "execution_time": "2539 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    if n > 1:\n\n        if n > 2:\n            qc.cx(0, n-1)\n\n        for i in range(0, n//2):\n            qc.cx(i, i+1)\n      \n        for i in range(n-1, n//2+1, -1):\n            qc.cx(i, i-1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A700E7ACC8A38", "submission_order": 1, "result": "RE", "execution_time": "1117 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(n-1):\n        qc.c(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A700E7ACC8A38", "submission_order": 2, "result": "DLE", "execution_time": "1303 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(n-1):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A700E7ACC8A38", "submission_order": 3, "result": "DLE", "execution_time": "1091 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(0, n-1, 10):\n        for j in range(i, min(i+10, n-1)):\n            qc.cx(j, j+1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A700E7ACC8A38", "submission_order": 4, "result": "RE", "execution_time": "1281 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(n - 1):\n        qc.h(i + 1)\n        qc.ccx(0, i, i + 1)\n        qc.h(i + 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7165E93272A6", "submission_order": 1, "result": "WA", "execution_time": "1680 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    qc.cx(control_qubit=0, target_qubit=1)\n    \n    for i in range(3,n,2):\n        qc.cx(control_qubit=0, target_qubit=i-1)\n        qc.cx(control_qubit=1, target_qubit=i)\n        \n        \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7165E93272A6", "submission_order": 2, "result": "WA", "execution_time": "1990 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    qc.cx(control_qubit=0, target_qubit=1)\n    \n    for i in range(2,n-1,2):\n        qc.cx(control_qubit=0, target_qubit=i)\n        qc.cx(control_qubit=1, target_qubit=i+1)\n        \n        \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7165E93272A6", "submission_order": 3, "result": "AC", "execution_time": "1997 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    qc.cx(control_qubit=0, target_qubit=1)\n    \n    for i in range(2,n-1,2):\n        qc.cx(control_qubit=0, target_qubit=i)\n        qc.cx(control_qubit=1, target_qubit=i+1)\n        \n    \n    if(n%2!=0):\n       qc.cx(control_qubit=0, target_qubit=n-1) \n    \n        \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A71EF9A1C9F95", "submission_order": 1, "result": "AC", "execution_time": "2137 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    middle = n // 2\n    qc.h(middle)\n    for i in range(middle, n - 1):\n        qc.cx(i, i + 1)\n    for i in range(middle, 0, -1):\n        qc.cx(i, i - 1)\n    qc.z(middle)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A72870739AD8B", "submission_order": 1, "result": "RE", "execution_time": "1257 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n >= 8:\n        qc.cx(0, 8)\n    if n >= 12:\n        qc.cx(8, 12)\n    if n >= 14:\n        qc.cx(12, 14)\n    if n >= 15:\n        qc.cx(14, 15)\n    if n >= 4:\n        qc.cx(0, 4)\n    if n >= 6:\n        qc.cx(4, 6)\n    if n >= 7:\n        qc.cx(6, 7)\n    if n >= 2:\n        qc.cx(0, 2)\n    if n >= 3:\n        qc.cx(2, 3)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A72870739AD8B", "submission_order": 2, "result": "WA", "execution_time": "1219 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n >= 9:\n        qc.cx(0, 8)\n    if n >= 13:\n        qc.cx(8, 12)\n    if n >= 15:\n        qc.cx(12, 14)\n    if n >= 5:\n        qc.cx(0, 4)\n    if n >= 7:\n        qc.cx(4, 6)\n    if n >= 8:\n        qc.cx(6, 7)\n    if n >= 3:\n        qc.cx(0, 2)\n    if n >= 4:\n        qc.cx(2, 3)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A72870739AD8B", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n >= 9:\n        qc.cx(0, 8)\n    if n >= 10:\n        qc.cx(8, 9)\n    if n >= 11:\n        qc.cx(8, 10)\n    if n >= 12:\n        qc.cx(10, 11)\n    if n >= 13:\n        qc.cx(8, 12)\n    if n >= 14:\n        qc.cx(12, 13)\n    if n >= 15:\n        qc.cx(12, 14)\n    if n >= 5:\n        qc.cx(0, 4)\n    if n >= 6:\n        qc.cx(4, 5)\n    if n >= 7:\n        qc.cx(4, 6)\n    if n >= 8:\n        qc.cx(6, 7)\n    if n >= 3:\n        qc.cx(0, 2)\n    if n >= :\n        qc.cx(2, 3)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A72870739AD8B", "submission_order": 4, "result": "AC", "execution_time": "2021 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n >= 9:\n        qc.cx(0, 8)\n    if n >= 10:\n        qc.cx(8, 9)\n    if n >= 11:\n        qc.cx(8, 10)\n    if n >= 12:\n        qc.cx(10, 11)\n    if n >= 13:\n        qc.cx(8, 12)\n    if n >= 14:\n        qc.cx(12, 13)\n    if n >= 15:\n        qc.cx(12, 14)\n    if n >= 5:\n        qc.cx(0, 4)\n    if n >= 6:\n        qc.cx(4, 5)\n    if n >= 7:\n        qc.cx(4, 6)\n    if n >= 8:\n        qc.cx(6, 7)\n    if n >= 3:\n        qc.cx(0, 2)\n    if n >= 4:\n        qc.cx(2, 3)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7405ADD08DBA", "submission_order": 1, "result": "AC", "execution_time": "2122 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.x(0)\n\tqc.h(0)\n\tl = 1\n\twhile l < n:\n\t\tr = min(n, 2 * l)\n\t\tfor i in range(l, r):\n\t\t\tqc.cx(i - l, i)\n\t\tl = r\n\treturn qc\n'''"}
{"problem": "QPC002_A4", "user": "A7456E98CECB0", "submission_order": 1, "result": "RE", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n - 1):\n        cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7456E98CECB0", "submission_order": 2, "result": "DLE", "execution_time": "1115 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7456E98CECB0", "submission_order": 3, "result": "AC", "execution_time": "2071 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for b in reversed(range(5)):\n        i = 0\n        while True:\n            if i + (1<<b) >= n:\n                break\n            qc.cx(i, i + (1<<b))\n            i += (1<<(b+1))\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A745FD13948F5", "submission_order": 1, "result": "WA", "execution_time": "1129 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    entangled = [0, 1]\n    remaining = list(range(2, n))\n    while len(remaining) != 0: \n        for i in entangled:\n            tbe = remaining[-1]\n            qc.cx(i, tbe)\n            entangled.append(tbe)\n            remaining.pop()\n            if len(remaining) == 0:\n                break\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A745FD13948F5", "submission_order": 2, "result": "AC", "execution_time": "2302 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    old_entangled = [0, 1]\n    new_entangled = [i for i in old_entangled]\n    remaining = list(range(2, n))\n    while len(remaining) != 0: \n        for i in old_entangled:\n            tbe = remaining[-1]\n            qc.cx(i, tbe)\n            new_entangled.append(tbe)\n            remaining.pop()\n            if len(remaining) == 0:\n                break\n        old_entangled = [i for i in new_entangled]  \n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A75CCE85667BA", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    a=1\n    while (a<n) {\n        for i in range(a):\n            if i+a<n:\n                qc.cx(i,i+a)\n        a*=2\n    }\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A75CCE85667BA", "submission_order": 2, "result": "AC", "execution_time": "2352 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    a=1\n    while a<n:\n        for i in range(a):\n            if i+a<n:\n                qc.cx(i,i+a)\n        a*=2\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7B34BD914093", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n   qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7B34BD914093", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n   qc.h(0)\n    for i in range(1, n):\n        qc.mct(list(range(n-1)), n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7B34BD914093", "submission_order": 3, "result": "RE", "execution_time": "1186 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.mct(list(range(n-1)), n-1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7B34BD914093", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.mct((i-1)), n-1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7BC453EF2944", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7BC453EF2944", "submission_order": 2, "result": "DLE", "execution_time": "1648 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7BC453EF2944", "submission_order": 3, "result": "DLE", "execution_time": "1461 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(0, n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A7BC453EF2944", "submission_order": 4, "result": "WA", "execution_time": "1070 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cz(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A819AA4DE17C1", "submission_order": 1, "result": "RE", "execution_time": "1818 ms", "memory": "156 MiB", "code": "'''python\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to all other qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply a phase shift to the entire state\n    qc.z(0)  # This applies a Z gate to the first qubit, which adds a phase of π to |1>\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A819AA4DE17C1", "submission_order": 2, "result": "DLE", "execution_time": "2049 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to all other qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply a phase shift to the entire state\n    qc.z(0)  # This applies a Z gate to the first qubit, which adds a phase of π to |1>\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A81E608101AD3", "submission_order": 1, "result": "DLE", "execution_time": "1267 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.h(0)\n        return qc\n\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(0, i+1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A81E608101AD3", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "251 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    coeffs = [0 for _ in range(2**n)]\n    coeffs[0] = 1/math.sqrt(2)\n    coeffs[-1] = -1/math.sqrt(2)\n    qc.initialize(coeffs)\n    return qc.decompose(reps=5)\n'''"}
{"problem": "QPC002_A4", "user": "A81E608101AD3", "submission_order": 3, "result": "DLE", "execution_time": "1494 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    coeffs = [0 for _ in range(2**n)]\n    coeffs[0] = 1/math.sqrt(2)\n    coeffs[-1] = -1/math.sqrt(2)\n    qc.initialize(coeffs)\n    return qc.decompose(reps=20)\n'''"}
{"problem": "QPC002_A4", "user": "A81E608101AD3", "submission_order": 4, "result": "WA", "execution_time": "1651 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.h(0)\n        return qc\n\n    step = 1\n    while step < n:\n        for i in range(0, n, step * 2):\n            if i + step < n:\n                qc.cx(i, i + step)\n        step *= 2\n\n    qc.z(range(n))\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A81E608101AD3", "submission_order": 5, "result": "AC", "execution_time": "1924 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.h(0)\n        return qc\n\n    qc.h(0)\n    for i in range(n-1):\n        if i % 2 == 0:\n            qc.cx(0, i+1)\n        else:\n            qc.cx(1, i+1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8225D42D555B", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    def rec(l, r):\n        if r - l <= 1:\n            return\n        m = (l + r) // 2\n        qc.cx(l, m)\n        rec(l, m)\n        rec(m, r)\n    rec(0, n)\n    # for i in range(1, n):\n    #     qc.cx(0, i)\n    return qc\n\n\nif __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    import numpy as np\n    n = 15\n    qc = solve(n)\n    sv = Statevector(qc)\n    print(sv)\n    print(qc)\n    print(f\"{qc.depth() = }\")\n#     sv = Statevector.from_label('+++')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_A4", "user": "A8225D42D555B", "submission_order": 2, "result": "AC", "execution_time": "2365 ms", "memory": "161 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    def rec(l, r):\n        if r - l <= 1:\n            return\n        m = (l + r) // 2\n        qc.cx(l, m)\n        rec(l, m)\n        rec(m, r)\n    rec(0, n)\n    # for i in range(1, n):\n    #     qc.cx(0, i)\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     n = 15\n#     qc = solve(n)\n#     sv = Statevector(qc)\n#     print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_A4", "user": "A8366783C1CE4", "submission_order": 1, "result": "WA", "execution_time": "1170 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cs(i-1, i)\n\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A847549308022", "submission_order": 1, "result": "AC", "execution_time": "2266 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    count = 1\n    while count < n:\n        add = 0\n        for i in range(count):\n            if n - 1 < count + i:\n                break\n            qc.cx(i, count + i)\n            add += 1\n        count += add\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A888F96D5D419", "submission_order": 1, "result": "DLE", "execution_time": "1182 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n-1)\n    qc.z(n-1)\n    for i in range(n-1):\n        qc.cx(n-1,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8A41FFE919B6", "submission_order": 1, "result": "AC", "execution_time": "1609 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef rec(i: int, l: int, qc: QuantumCircuit):\n    qc.cx(i, i+l//2)\n    if l//2>1:\n        rec(i, l//2, qc)\n    if l-l//2>1:\n        rec(i+l//2, l-l//2, qc)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    rec(0, n, qc)\n    qc.cz(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8BED3ECBDC47", "submission_order": 1, "result": "RE", "execution_time": "1295 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0);\n    qc.h(0);\n    a = deque(range(1, n));\n    b = deque([0]);\n    while len(a) > 0:\n        for i in b:\n            if len(a) == 0:\n                break;\n            else:\n                c = a.pop();\n                qc.cx(i, c);\n                b.append(c);\n\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8E16E4A6763D", "submission_order": 1, "result": "DLE", "execution_time": "1188 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8E16E4A6763D", "submission_order": 2, "result": "DLE", "execution_time": "1528 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i - 1, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8E16E4A6763D", "submission_order": 3, "result": "RE", "execution_time": "1364 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    c.cx(0, range(1, n))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8E16E4A6763D", "submission_order": 4, "result": "RE", "execution_time": "1146 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, range(1, ))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8E16E4A6763D", "submission_order": 5, "result": "RE", "execution_time": "1060 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x()\n    qc.h()\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8FDC3E118901", "submission_order": 1, "result": "DLE", "execution_time": "1149 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(0, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8FDC3E118901", "submission_order": 2, "result": "DLE", "execution_time": "1129 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, range(1, n))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A8FDC3E118901", "submission_order": 3, "result": "AC", "execution_time": "2009 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    st = list(range(n-1, 0, -1))\n    nn = 1\n    while st:\n        for i in range(nn):\n            j = st.pop()\n            qc.cx(i, j)\n            nn += 1\n            if len(st) == 0:\n                break\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 1, "result": "DLE", "execution_time": "1460 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 2, "result": "RE", "execution_time": "1264 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    half = n / 2\n    first = n - half - 1\n    for i in range(first):\n        qc.cx(0, i + 1)\n    for i in range(half):\n        qc.cx(0, i + 1 + first)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 3, "result": "RE", "execution_time": "1257 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    half = n // 2\n    first = n - half - 1\n    for i in range(first):\n        qc.cx(0, i + 1)\n    for i in range(half):\n        qc.cx(0, i + 1 + firs)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 4, "result": "RE", "execution_time": "1260 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    half = n // 2\n    first = n - half - 1\n    for i in range(first):\n        qc.cx(0, i + 1)\n    for i in range(half):\n        qc.cx(first - 1, i + 1 + firs)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    half = n // 2\n    first = n - half - 1\n    for i in range(first):\n        qc.cx(0, i + 1)\n    for i in range(half):\n        qc.cx(first - , i + 1 + first)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 6, "result": "RE", "execution_time": "1659 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    half = n // 2\n    first = n - half - 1\n    for i in range(first):\n        qc.cx(0, i + 1)\n    for i in range(half):\n        qc.cx(first - 1, i + 1 + first)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 7, "result": "RE", "execution_time": "2268 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    half = n // 2\n    first = n - half - 1\n    for i in range(first):\n        qc.cx(0, i + 1)\n    for i in range(half):\n        qc.cx(1, i + 1 + first)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 8, "result": "RE", "execution_time": "2268 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    half = n // 2\n    first = n - half - 1\n    for i in range(first):\n        qc.cx(0, i + 1)\n    for i in range(half):\n        qc.cx(1, i + 1 + first)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 9, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n = 2:\n        for i in range(n - 1):\n            qc.cx(0, i + 1)\n    else:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 10, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n == 2:\n        for i in range(n -):\n            qc.cx(0, i + 1)\n    else:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A929C23A96376", "submission_order": 11, "result": "AC", "execution_time": "2140 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n == 2:\n        for i in range(n - 1):\n            qc.cx(0, i + 1)\n    else:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A92A65126FEA1", "submission_order": 1, "result": "DLE", "execution_time": "1892 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A92A65126FEA1", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,transpile\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n\n    qc = transpile(qc,optimization_level=3)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A92A65126FEA1", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,transpile\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    control_qubit = [0]\n    target_qubit = list(range(1,n))\n    for target in target_qubit:\n        qc.mcx(control_qubit,target)\n\n    # qc = transpile(qc,optimization_level=3)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A92A65126FEA1", "submission_order": 4, "result": "DLE", "execution_time": "1650 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    control_qubit = [0]\n    target_qubit = list(range(1,n))\n    for target in target_qubit:\n        qc.mcx(control_qubit,target)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A92A65126FEA1", "submission_order": 5, "result": "RE", "execution_time": "1144 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    control_qubit = [0]\n    target_qubit = list(range(1,n))\n    qc.cmx(control_qubit,target_qubit)\n    # for target in target_qubit:\n    #     qc.mcx(control_qubit,target)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A92A65126FEA1", "submission_order": 6, "result": "RE", "execution_time": "1297 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    control_qubit = [0]\n    target_qubit = list(range(1,n))\n    qc.cxn-1(control_qubit,target_qubit)\n    # for target in target_qubit:\n    #     qc.mcx(control_qubit,target)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A954F15A9EEA6", "submission_order": 1, "result": "RE", "execution_time": "1410 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(0)\n    \n\n    qc.cx(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 4)\n    qc.cx(0, 8)\n    \n    qc.cx(1, 3)\n    qc.cx(2, 5)\n    qc.cx(4, 6)\n    qc.cx(8, 7)\n    \n    qc.cx(3, 9)\n    qc.cx(5, 10)\n    qc.cx(6, 11)\n    qc.cx(7, 12)\n    \n    qc.cx(9, 13)\n    qc.cx(10, 14)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A954F15A9EEA6", "submission_order": 2, "result": "AC", "execution_time": "2882 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(0)\n\n    x=[1]\n    for i in range(1,n):\n        # print(x)\n        y=min(x)\n        for j in range(len(x)):\n            if y==x[j]:\n                break\n        qc.cx(j,i)\n        x[j]+=1\n        x+=x[j],\n        \n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A959E9CC7235E", "submission_order": 1, "result": "RE", "execution_time": "1448 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if n%2 ==1:\n        qc.cx(0,n-1)\n    qc.cx(0, n//2)        \n    for i in range(n//2):\n        qc.cx(i,i+1)\n        qc.cx(n//2+i,n//2+i+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A959E9CC7235E", "submission_order": 2, "result": "AC", "execution_time": "2144 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    if n%2 == 1:\n        qc.cx(0,n-1)\n    qc.cx(0, n//2)        \n    for i in range(n//2-1):\n        qc.cx(i,i+1)\n        qc.cx(n//2+i,n//2+i+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A96EE29EB4D1A", "submission_order": 1, "result": "AC", "execution_time": "1793 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ceil,log2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    step = 2**ceil(log2(n))\n    while step:\n        for i in range(0, n, 2 * step):\n            if i + step < n:\n                qc.cx(i, i + step)\n        step //= 2\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9C44EA16F2A0", "submission_order": 1, "result": "WA", "execution_time": "1255 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    end = 1\n    while end < n:\n        for left in range(end):\n            qc.cx(left, end)\n            end += 1\n            if end == n:\n                break\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9C44EA16F2A0", "submission_order": 2, "result": "AC", "execution_time": "2015 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    end = 1\n    while end < n:\n        for left in range(end):\n            qc.cx(left, end)\n            end += 1\n            if end == n:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9E1B3144C1BB", "submission_order": 1, "result": "AC", "execution_time": "1818 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i//2, i)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9E23B4701EDB", "submission_order": 1, "result": "RE", "execution_time": "1172 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    qc.h(0)\n    if n <= 4:\n        for i in range(1,n):\n            qc.cx(0,i)\n    else:\n        for i in range(4):\n            for j in range(i+1):\n                if 2**i+j > n:\n                    break\n                qc.cx(j,2**i+j)\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9E23B4701EDB", "submission_order": 2, "result": "RE", "execution_time": "1498 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    qc.h(0)\n    if n <= 4:\n        for i in range(1,n):\n            qc.cx(0,i)\n    else:\n        f = 0\n        for i in range(4):\n            for j in range(i+1):\n                if 2**i+j > n:\n                    f = 1\n                    break\n                qc.cx(j,2**i+j)\n            if f == 1:\n                break\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9E23B4701EDB", "submission_order": 3, "result": "RE", "execution_time": "1548 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    qc.h(0)\n    if n <= 4:\n        for i in range(1,n):\n            qc.cx(0,i)\n    else:\n        f = 0\n        for i in range(4):\n            for j in range(i+1):\n                if 2**i+j > n:\n                    f = 1\n                    break\n                qc.cx(j,2**i+j)\n            if f == 1:\n                break\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9E23B4701EDB", "submission_order": 4, "result": "WA", "execution_time": "1230 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    qc.h(0)\n    if n <= 4:\n        for i in range(1,n):\n            qc.cx(0,i)\n    else:\n        f = 0\n        for i in range(4):\n            for j in range(i+1):\n                if 2**i+j >= n:\n                    f = 1\n                    break\n                qc.cx(j,2**i+j)\n            if f == 1:\n                break\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9E23B4701EDB", "submission_order": 5, "result": "WA", "execution_time": "1233 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    qc.h(0)\n    f = 0\n    for i in range(4):\n        for j in range(i+1):\n            if 2**i+j >= n:\n                f = 1\n                break\n            qc.cx(j,2**i+j)\n        if f == 1:\n            break\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9E23B4701EDB", "submission_order": 6, "result": "AC", "execution_time": "2109 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(n//2-1)\n    qc.cx(n//2-1,n//2)\n    for i in range((n-2)//2+1):\n        if 0 <= n//2-2-i < n:\n            qc.cx(n//2-1,n//2-2-i)\n        if 0 <= n//2+i+1 < n:\n            qc.cx(n//2,n//2+i+1)\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9EE0880EB81A", "submission_order": 1, "result": "DLE", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "A9EE0880EB81A", "submission_order": 2, "result": "WA", "execution_time": "1176 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        if(n<9):\n            qc.cx(i,i+1)\n            qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0CC08834507", "submission_order": 1, "result": "DLE", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(n-1)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0CC08834507", "submission_order": 2, "result": "DLE", "execution_time": "1413 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(n-1)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0EC6BAD376C", "submission_order": 1, "result": "RE", "execution_time": "1893 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z()\n    return qc\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0EC6BAD376C", "submission_order": 2, "result": "RE", "execution_time": "1481 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n-1):\n        qc.cx(0,i)\n\n    qc.cx(1,n)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0EC6BAD376C", "submission_order": 3, "result": "AC", "execution_time": "1926 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(2,n-1,2):\n        qc.cx(0,i)\n        qc.cx(1,i+1)\n    if n%2!=0:\n        qc.cx(0,n-1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0ED04800358", "submission_order": 1, "result": "DLE", "execution_time": "1539 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0ED04800358", "submission_order": 2, "result": "RE", "execution_time": "1357 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    def cnot_(sta, end):\n        if sta == end:\n            return\n        mid = (sta + end) // 2\n        circuit.cx(qr[sta], qr[mid])\n        cnot_(sta, mid)\n        cnot_(mid, end)\n\n    cnot_(0, n)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0ED04800358", "submission_order": 3, "result": "RE", "execution_time": "1194 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    def cnot_(sta, end):\n        if sta == end:\n            return\n        mid = (sta + end) // 2\n        qc.cx(sta, mid)\n        cnot_(sta, mid)\n        cnot_(mid, end)\n\n    cnot_(0, n)\n\n    qc.z()\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0ED04800358", "submission_order": 4, "result": "RE", "execution_time": "1100 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    circuit = QuantumCircuit(qr)\n\n    qc.h(0)\n\n    def cnot_(sta, end):\n        if sta == end:\n            return\n        mid = (sta + end) // 2\n        circuit.cx(sta, mid)\n        cnot_(sta, mid)\n        cnot_(mid, end)\n\n    cnot_(0, n)\n\n    qc.z()\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0ED04800358", "submission_order": 5, "result": "RE", "execution_time": "1147 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    def cnot_(sta, end):\n        if sta == end:\n            return\n        mid = (sta + end) // 2\n        qc.cx(sta, mid)\n        cnot_(sta, mid)\n        cnot_(mid, end)\n\n    cnot_(0, n)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA0ED04800358", "submission_order": 6, "result": "AC", "execution_time": "1716 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    def cnot_(sta, end):\n        if sta >= end - 1:\n            return\n        mid = (sta + end) // 2\n        qc.cx(sta, mid)\n        cnot_(sta, mid)\n        cnot_(mid, end)\n\n    cnot_(0, n)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA15AF65AFBF0", "submission_order": 1, "result": "DLE", "execution_time": "1240 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA15AF65AFBF0", "submission_order": 2, "result": "WA", "execution_time": "1529 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    step = 1\n    while step < n:\n        for i in range(0, n - step, 2 * step):\n            qc.cx(i, i + step)\n        step *= 2\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA15AF65AFBF0", "submission_order": 3, "result": "WA", "execution_time": "1474 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    for i in range(n):\n        for j in range(i + 1, n):\n            qc.cp(3.141592653589793 / (2 ** (j - i)), j, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA15AF65AFBF0", "submission_order": 4, "result": "WA", "execution_time": "1177 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.cz(0, 1)\n    for i in range(1, n-1, 2):\n        qc.cx(i, i+1)\n    for i in range(2, n-1, 2):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA15AF65AFBF0", "submission_order": 5, "result": "WA", "execution_time": "1164 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply CNOT gates in parallel\n    step = 1\n    while step < n:\n        for i in range(0, n - step, step * 2):\n            qc.cx(i, i + step)\n        step *= 2\n    \n    # Apply Z gate to the last qubit\n    qc.z(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA15AF65AFBF0", "submission_order": 6, "result": "AC", "execution_time": "1630 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i//2,i)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA299C98E096F", "submission_order": 1, "result": "DLE", "execution_time": "1162 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  qc.x(0)\n  qc.h(0)\n  qc.cx(0, range(1, n))\n  return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA299C98E096F", "submission_order": 2, "result": "AC", "execution_time": "1772 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  qc.x(0)\n  qc.h(0)\n  a = 1\n  while a < n:\n    for i in range(min(a, n - a)):\n      qc.cx(i, a + i)\n    a *= 2\n  return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA4731191E59A", "submission_order": 1, "result": "DLE", "execution_time": "1627 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n - 1):\n        qc.cx(0,i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA4731191E59A", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n\n    if n == 2:\n        return qc\n\n    loop_num = int( (n - 2) / 2 )\n    for i in range(loop_num):\n        qc.cx(0, i + 2)\n        if n %% 2 == 0:\n            qc.cx(1, i + 3)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA4731191E59A", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n\n    if n > 2:\n        loop_num = int( (n - 2) / 2 )\n        for i in range(loop_num):\n            qc.cx(0, i + 2)\n            if n %% 2 == 0:\n                qc.cx(1, i + 3)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA4731191E59A", "submission_order": 4, "result": "WA", "execution_time": "1358 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0, 1)\n\n    if n > 2:\n        loop_num = int( (n - 2) / 2 )\n        for i in range(loop_num):\n            qc.cx(0, i + 2)\n            if n % 2 == 0:\n               qc.cx(1, i + 3)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA5CBC82E6E51", "submission_order": 1, "result": "DLE", "execution_time": "1141 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Step 1: Apply Hadamard gate to the first qubit to create superposition\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to entangle the first qubit with all other qubits in parallel\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce phase difference\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA5CBC82E6E51", "submission_order": 2, "result": "DLE", "execution_time": "1661 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply a sequence of CNOT gates in logarithmic layers to entangle qubits\n    # Each step entangles a pair of qubits, reducing the depth\n    num_layers = 0\n    for i in range(1, n):\n        qc.cx(0, i)\n        num_layers += 1\n        if num_layers == 9:\n            break\n    \n    # Step 3: Apply Z gate to the first qubit to introduce phase difference\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA5CBC82E6E51", "submission_order": 3, "result": "RE", "execution_time": "1120 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply a sequence of CNOT gates in logarithmic layers to entangle qubits\n    # Each step entangles a pair of qubits, reducing the depth\n    i = 1\n    while i < n:\n        for j in range(0, n, i*2):\n            qc.cx(j, j+i)\n        i *= 2\n    \n    # Step 3: Apply Z gate to the first qubit to introduce phase difference\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA731CB32F42C", "submission_order": 1, "result": "DLE", "execution_time": "1319 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA731CB32F42C", "submission_order": 2, "result": "AC", "execution_time": "2098 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx((i - 1) // 2, i)\n    \n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA74B9F2F7AC7", "submission_order": 1, "result": "AC", "execution_time": "1759 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.cx(i//2,i)\n    \n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA7A4A17C432A", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-1)\n        qc.cx(i,i+1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA7A4A17C432A", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-1)\n        qc.cx(i,i+1)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA7A4A17C432A", "submission_order": 3, "result": "DLE", "execution_time": "1878 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=0\n    if n>2:\n        for i in range(n-2):\n            if c%2==0:\n                qc.cx(0,i+2)\n            else:\n                qc.cx(1,i+2)\n\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA7A4A17C432A", "submission_order": 4, "result": "AC", "execution_time": "2277 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=0\n    if n>2:\n        for i in range(n-2):\n            if c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            else:\n                qc.cx(1,i+2)\n                c=c+1\n\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 1, "result": "DLE", "execution_time": "1724 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 2, "result": "RE", "execution_time": "1961 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n / 2):\n        qc.ccx(0, i, i + 1)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 3, "result": "RE", "execution_time": "1731 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n / 2, 2):\n        qc.ccx(0, i, i + 1)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 4, "result": "RE", "execution_time": "1929 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n / 2 - 1, 2):\n        qc.ccx(0, i, i + 1)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 5, "result": "RE", "execution_time": "1875 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(1, n, 2):\n        qc.ccx(0, i, i + 1)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 6, "result": "DLE", "execution_time": "1858 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.(0, n - 1)\n    if n % 2 == 0:\n        for i in range(1, n / 2):\n            qc.cx(0, i)\n        for i in range(n - 1, n / 2):\n            qc.cx(n - 1, i)\n    else:\n        for i in range(1, n / 2):\n            qc.cx(0, i)\n        for i in range(n - 1, n / 2 - 1):\n            qc.cx(n - 1, i)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 8, "result": "RE", "execution_time": "1682 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n - 1)\n    if n % 2 == 0:\n        for i in range(1, n // 2):\n            qc.cx(0, i)\n        for i in range(n - 1, n // 2, -1):\n            qc.cx(n - 1, i)\n    else:\n        for i in range(1, n // 2):\n            qc.cx(0, i)\n        for i in range(n - 1, n // 2 - 1, -1):\n            qc.cx(n - 1, i)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 9, "result": "RE", "execution_time": "1727 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n - 1)\n    if n % 2 == 0:\n        for i in range(1, n // 2):\n            qc.cx(0, i)\n        for i in range(n - 1, n // 2, -1):\n            qc.cx(n - 1, i)\n    else:\n        for i in range(1, n // 2):\n            qc.cx(0, i)\n        for i in range(n - 1, n // 2 - 1, -1):\n            qc.cx(n - 1, i)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 10, "result": "WA", "execution_time": "2063 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n - 1)\n    if n % 2 == 0:\n        for i in range(1, n // 2):\n            qc.cx(0, i)\n        for i in range(n - 2, n // 2, -1):\n            qc.cx(n - 1, i)\n    else:\n        for i in range(1, n // 2):\n            qc.cx(0, i)\n        for i in range(n - 2, n // 2 - 1, -1):\n            qc.cx(n - 1, i)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 11, "result": "WA", "execution_time": "1839 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n // 2):\n        qc.cx(0, i)\n    for i in range(n - 2, n // 2, -1):\n        qc.cx(n - 1, i)\n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA98FC6D67D30", "submission_order": 12, "result": "AC", "execution_time": "2110 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n // 2):\n        qc.cx(0, i)\n    for i in range(n - 2, n // 2 - 1, -1):\n        qc.cx(n - 1, i)\n    \n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AA9D851E23030", "submission_order": 1, "result": "AC", "execution_time": "2044 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n_bits)\n    qc.h(0)\n    m = 0\n    while 1 << m < n_bits: m += 1\n    for k in range(m):\n        d = 1 << k\n        for i in range(d):\n            if i + d < n_bits: qc.cx(i, i + d)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = get_ghz_circuit(n)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAA9ECEDC47BE", "submission_order": 1, "result": "AC", "execution_time": "2057 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    qc.h(0)\n\n    def f(x, y):\n        if y < n:\n            qc.cx(x, y)\n\n    f(0, 1)\n\n    f(0, 2)\n    f(1, 3)\n\n    f(0, 4)\n    f(1, 5)\n    f(2, 6)\n    f(3, 7)\n\n    f(0, 8)\n    f(1, 9)\n    f(2, 10)\n    f(3, 11)\n    f(4, 12)\n    f(5, 13)\n    f(6, 14)\n    f(7, 15)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAC2034AD661D", "submission_order": 1, "result": "DLE", "execution_time": "1809 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAC2034AD661D", "submission_order": 2, "result": "WA", "execution_time": "2055 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(2, n-1, 2):\n        qc.cx(0, i)\n        qc.cx(1, i+1)\n\n    if n % 2 != 0:\n        qc.cx(0, n-1)\n\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAC2034AD661D", "submission_order": 3, "result": "AC", "execution_time": "2330 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    for i in range(2, n-1, 2):\n        qc.cx(0, i)\n        qc.cx(1, i+1)\n\n    if n % 2 != 0:\n        qc.cx(0, n-1)\n\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD50D90148A3", "submission_order": 1, "result": "WA", "execution_time": "3000 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(2, n - 1, 2):\n        qc.cx(0, i)\n        qc.cx(1, i + 1)\n    if n % 2 != 0:\n        qc.cx(0, n - 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD50D90148A3", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, n - 1, 2):\n        qc.cx(0, i)\n        qc.cx(1, i + 1)\n    if n % 2 != 0:\n        qc.cx(0, n - 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD81E9884573", "submission_order": 1, "result": "WA", "execution_time": "1846 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n//2):\n        qc.cswap(0, 2*i, 2*i+1)\n    if n % 2 == 1:\n        qc.cx(0,n-1)\n    qc.z(0)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD81E9884573", "submission_order": 2, "result": "WA", "execution_time": "1111 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n//2):\n        qc.cswap(0, 2*i-1, 2*i)\n    if n % 2 == 0:\n        qc.cx(0,n-1)\n    qc.z(0)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD81E9884573", "submission_order": 3, "result": "RE", "execution_time": "1456 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j, 2**i + j)\n    qc.z(0)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD81E9884573", "submission_order": 4, "result": "AC", "execution_time": "2016 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j, 2**i + j)\n    qc.z(0)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD8A73417A2C", "submission_order": 1, "result": "DLE", "execution_time": "1431 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n, 1):\n        if i!=0:\n            qc.cx(0,i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD8A73417A2C", "submission_order": 2, "result": "AC", "execution_time": "1772 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    for i in range(2,n-1,2):\n        qc.cx(0,i)\n        qc.cx(i,i+1)\n    \n    if n%2!=0:\n        qc.cx(0,n-1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD92D87A7E78", "submission_order": 1, "result": "DLE", "execution_time": "1349 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD92D87A7E78", "submission_order": 2, "result": "DLE", "execution_time": "1126 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n\n    if n>1:\n        qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD92D87A7E78", "submission_order": 3, "result": "DLE", "execution_time": "1266 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n>10:\n        n = 10\n\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD92D87A7E78", "submission_order": 4, "result": "WA", "execution_time": "1166 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n>9:\n        n = 9\n\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAD92D87A7E78", "submission_order": 5, "result": "WA", "execution_time": "1084 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n>10:\n        n1=10\n    else:\n        n1 = n\n    # Apply CNOT gates to create entanglement\n    for i in range(n1-1):\n        qc.cx(i, i + 1)\n    \n    if qc.depth()<10:\n        qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAE3537E7A4DE", "submission_order": 1, "result": "DLE", "execution_time": "1204 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AAE3537E7A4DE", "submission_order": 2, "result": "AC", "execution_time": "2139 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n == 2:\n        qc.cx(0, 1)\n    elif n == 3:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n    elif n== 4:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n    elif n == 5:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n    elif n == 6:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n    elif n == 7:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)\n    elif n == 8:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n    elif n == 9:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n    elif n == 10:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)\n    elif n == 11:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)\n    elif n == 12:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)        \n        qc.cx(4, 11)\n    elif n == 13:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)        \n        qc.cx(4, 11)        \n        qc.cx(3, 12)\n    elif n == 14:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)        \n        qc.cx(4, 11)        \n        qc.cx(3, 12)        \n        qc.cx(2, 13)\n    elif n == 15:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)        \n        qc.cx(4, 11)        \n        qc.cx(3, 12)        \n        qc.cx(2, 13)\n        qc.cx(1, 14)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB00E195C2A0C", "submission_order": 1, "result": "DLE", "execution_time": "1258 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(0, n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB00E195C2A0C", "submission_order": 2, "result": "RE", "execution_time": "1178 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(0, n, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, n, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB00E195C2A0C", "submission_order": 3, "result": "RE", "execution_time": "1094 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(0, n, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, n-1, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB00E195C2A0C", "submission_order": 4, "result": "RE", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(0, n, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, n-1, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB00E195C2A0C", "submission_order": 5, "result": "WA", "execution_time": "1224 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(0, n-1, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, n-1, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB00E195C2A0C", "submission_order": 6, "result": "WA", "execution_time": "1596 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(0, n-1, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, n-2, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB00E195C2A0C", "submission_order": 7, "result": "WA", "execution_time": "1104 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    if n%2 != 0:\n        e = n-1\n        o = n\n    else:\n        e = n\n        o = n-1\n\n    for i in range(0, e, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, 0, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB00E195C2A0C", "submission_order": 8, "result": "WA", "execution_time": "1263 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    if n%2 != 0:\n        e = n-1\n        o = n\n    else:\n        e = n\n        o = n-1\n\n    for i in range(0, e, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, o, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 1, "result": "RE", "execution_time": "1194 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,i)\n    qc.z()\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 2, "result": "DLE", "execution_time": "1443 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i-1,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 3, "result": "RE", "execution_time": "1209 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tgt = 1\n    p == 0\n    while tgt < n:\n        for i in range(2**p):\n            qc.cx(i,tgt)\n            tgt += 1\n        p += 1\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 4, "result": "RE", "execution_time": "1397 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tgt = 1\n    p = 0\n    while tgt < n:\n        for i in range(2**p):\n            qc.cx(i,tgt)\n            tgt += 1\n        p += 1\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 5, "result": "WA", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tgt = 1\n    p = 0\n    for i in range(2**p):\n        if tgt < n:\n            qc.cx(i,tgt)\n            tgt += 1\n        else:\n            break\n        p += 1\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 6, "result": "RE", "execution_time": "1110 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tgt = 1\n    for p in range(math.floor(math.log2(n))):\n        for i in range(0, n, 2**p):\n            if tgt < n:\n                qc.cx(i,tgt)\n                tgt += 1\n            else:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 7, "result": "RE", "execution_time": "1028 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tgt = 1\n    for p in range(math.floor(math.log2(n))):\n        for i in range(2**p):\n            if tgt < n:\n                qc.cx(i,tgt)\n                tgt += 1\n            else:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 8, "result": "RE", "execution_time": "1090 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tgt = 1\n    for p in range(math.ceil(math.log2(n))):\n        for i in range(2**p):\n            if tgt < n:\n                qc.cx(i,tgt)\n                tgt += 1\n            else:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB11E5B8D1CA9", "submission_order": 9, "result": "AC", "execution_time": "2119 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tgt = 1\n    for p in range(math.ceil(math.log2(n))):\n        for i in range(2**p):\n            if tgt < n:\n                qc.cx(i,tgt)\n                tgt += 1\n            else:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB16FD1D4696D", "submission_order": 1, "result": "DLE", "execution_time": "1170 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(0, n-1):\n        qc.cx(i, i+1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB16FD1D4696D", "submission_order": 2, "result": "WA", "execution_time": "1265 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    qc.mcx(list(range(1, n)), 0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB16FD1D4696D", "submission_order": 3, "result": "AC", "execution_time": "2151 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef get_min_depth(depth):\n    min_val = min(depth.values())\n    for (k, v) in depth.items():\n        if v == min_val:\n            return k\n\ndef get_unentangled_qubit(e, n):\n    for i in range(n):\n        if i not in e:\n            return i\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    entangled_qubits = [0, 1]\n    depth = dict()\n\n    depth[0] = 2\n    depth[1] = 2\n\n    while len(entangled_qubits) != n:\n\n        c = get_min_depth(depth)\n        t = get_unentangled_qubit(entangled_qubits, n)\n\n        qc.cx(c, t)\n        depth[c] = depth[c] + 1 \n        depth[t] = depth[c]\n        entangled_qubits.append(t)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB368A3046CDE", "submission_order": 1, "result": "DLE", "execution_time": "1090 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB368A3046CDE", "submission_order": 2, "result": "DLE", "execution_time": "1065 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB368A3046CDE", "submission_order": 3, "result": "DLE", "execution_time": "1112 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB587F9C2315C", "submission_order": 1, "result": "WA", "execution_time": "1850 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    idx = 1 # 次に設定するやつ\n    for i in range(0,idx):\n        # 設定済みのところから\n        if idx+i==n:\n            break\n        qc.cx(i, idx+i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB587F9C2315C", "submission_order": 2, "result": "AC", "execution_time": "2210 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    idx = 1 # 次に設定するやつ\n    while idx<n:\n        for i in range(0,idx):\n            # 設定済みのところから\n            if idx+i==n:\n                break\n            qc.cx(i, idx+i)\n        idx *= 2\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB71D270E124B", "submission_order": 1, "result": "AC", "execution_time": "2321 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for depth in range(4, -1, -1):\n        for i in range(0, n, 1<<(depth+1)):\n            if i+(1<<depth) < n:\n                qc.cx(i, i+(1<<depth))\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AB8B725668B06", "submission_order": 1, "result": "DLE", "execution_time": "1728 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 1, "result": "RE", "execution_time": "1179 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    qc.z(n - 1)\n    \n    qc.measure_all()\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 2, "result": "WA", "execution_time": "1109 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    qc.z(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 3, "result": "WA", "execution_time": "1183 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    qc.z(n - 1)\n    \n    qc.barrier()\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 4, "result": "WA", "execution_time": "1148 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.h(0)\n    qc.x(range(n))\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 5, "result": "WA", "execution_time": "1518 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    qc.z(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 6, "result": "WA", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    \n    for i in range(n // 2):\n        qc.cx(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 7, "result": "WA", "execution_time": "1716 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 8, "result": "DLE", "execution_time": "1130 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 9, "result": "RE", "execution_time": "1562 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = np.pi / 2\n    phi = 0\n    lambda_ = 0\n    for i in range(n):\n        qc.u(theta, phi, lambda_, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABF8E56341D49", "submission_order": 10, "result": "WA", "execution_time": "1398 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import numpy as np\n    theta = np.pi / 2\n    phi = 0\n    lambda_ = 0\n    for i in range(n):\n        qc.u(theta, phi, lambda_, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 1, "result": "WA", "execution_time": "1289 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Step 1: Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply X gates to all qubits\n    for i in range(n):\n        qc.x(i)\n    \n    # Step 3: Apply multi-controlled Z gate\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)  # Multi-controlled X (also called CCX or Toffoli gates)\n    qc.h(0)\n    \n    # Step 4: Undo the X gates\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 2, "result": "DLE", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates from the first qubit to all other qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to the first qubit to flip the sign of the |1...1> state\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 3, "result": "WA", "execution_time": "1099 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     # Step 1: Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply a multi-controlled Z gate (this can be achieved with an H-CX-H sandwich)\n    qc.h(n-1)  # Apply H to the last qubit\n    qc.mcx(list(range(n-1)), n-1)  # Apply multi-controlled X gate to the last qubit\n    qc.h(n-1)  # Apply H again to convert to a Z gate\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 4, "result": "WA", "execution_time": "1309 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply X gates to all qubits except the first\n    for i in range(1, n):\n        qc.x(i)\n    \n    # Step 3: Apply a controlled-Z gate with the first qubit as control\n    qc.cz(0, 1)\n    \n    # Step 4: Undo the X gates\n    for i in range(1, n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 5, "result": "WA", "execution_time": "1114 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply X (NOT) gate to all qubits except the first\n    for i in range(1, n):\n        qc.x(i)\n    \n    # Apply controlled-Z gate with the first qubit as control and all others as target\n    qc.cz(0, n-1)\n    \n    # Apply X (NOT) gate again to all qubits except the first\n    for i in range(1, n):\n        qc.x(i)\n    \n    # Apply Hadamard gate to the first qubit again\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 6, "result": "RE", "execution_time": "1411 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to create the superposition state\n    qc.h(0)\n    \n    # Apply a phase flip to the last qubit to create the -1 factor\n    if n > 1:\n        qc.x(n-1)\n        qc.h(n-1)\n        qc.mct(list(range(n-1)), n-1)\n        qc.h(n-1)\n        qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 7, "result": "RE", "execution_time": "1112 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to all qubits to create superposition\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply a phase flip to create the -1 factor\n    qc.x(n-1)\n    qc.h(n-1)\n    \n    qc.mct(list(range(n-1)), n-1)  # Multi-controlled Toffoli (CCNOT) gate\n    qc.h(n-1)\n    qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 8, "result": "WA", "execution_time": "1169 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     # Apply Hadamard gates to all qubits\n    qc.h(range(n))\n    \n    # Apply a controlled Z gate on the last qubit conditioned on the first three qubits being in state |111>\n    qc.mcx(list(range(n-1)), n-1)\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 9, "result": "DLE", "execution_time": "1046 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gates to entangle the first qubit with the others\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Apply Z gate to the first qubit to introduce the phase flip\n    qc.z(0)\n    \n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 10, "result": "RE", "execution_time": "1178 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gates to all qubits\n    qc.h(range(n))\n    \n    # Apply a multi-controlled Z gate on all qubits to flip the phase of the |1111> state\n    qc.append(MCXGate(n-1), list(range(n-1)) + [n-1])\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 11, "result": "DLE", "execution_time": "1153 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gates to all other qubits\n    for qubit in range(1, n):\n        qc.cx(0, qubit)\n    \n    # Apply a Z gate to introduce the phase flip\n    qc.z(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 12, "result": "WA", "execution_time": "1095 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to each qubit\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply CNOT gates to create the required superposition\n    for qubit in range(n-1):\n        qc.cx(qubit, qubit + 1)\n    \n    # Apply a Z gate to flip the phase of the final state\n    qc.z(n-1)\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 13, "result": "WA", "execution_time": "1242 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply X gates to all qubits\n    for i in range(n):\n        qc.x(i)\n    \n    # Step 3: Apply multi-controlled Z gate using controlled-X (CNOT) gates\n    qc.h(n-1)\n    for i in range(n-1):\n        qc.cx(i, n-1)\n    qc.h(n-1)\n    \n    # Step 4: Apply X gates again to all qubits\n    for i in range(n):\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ABFFD59BA1332", "submission_order": 14, "result": "AC", "execution_time": "2151 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n \n    for i in range(2, n - 1, 2):\n        qc.cx(0, i)\n        qc.cx(1, i + 1)\n \n    if n % 2 != 0:\n        qc.cx(0, n - 1)\n \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC16553C21030", "submission_order": 1, "result": "WA", "execution_time": "1501 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(n):\n        for j in range(i+1,n):\n            qc.cz(i,j)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC1EA669B6393", "submission_order": 1, "result": "DLE", "execution_time": "1543 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        i+=1\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC24F6DA44F7F", "submission_order": 1, "result": "AC", "execution_time": "1967 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.z(0)\n    m = 1\n    while m < n:\n        for i in range(m):\n            if i + m < n:\n                qc.cx(i, i + m)\n        m *= 2\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4061F48D6A8", "submission_order": 1, "result": "RE", "execution_time": "1307 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range((n-2)/2):\n        qc.cx(0, 2+i)\n    for i in range((n-2)/2):\n        qc.cx(1, 2+(n-2)/2+i)\n    if ((n-2)%2 == 1):\n        qc.cx(1, n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4061F48D6A8", "submission_order": 2, "result": "RE", "execution_time": "1099 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range((n-2)/2):\n        qc.cx(0, 2+i)\n    for i in range((n-2)/2):\n        qc.cx(1, 2+(n-2)/2+i)\n    if ((n-2)%2 == 1):\n        qc.cx(1, n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4061F48D6A8", "submission_order": 3, "result": "AC", "execution_time": "2051 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(int((n-2)/2)):\n        qc.cx(0, 2+i)\n    for i in range(int((n-2)/2)):\n        qc.cx(1, 2+int((n-2)/2)+i)\n    if ((n-2)%2 == 1):\n        qc.cx(1, n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 1, "result": "DLE", "execution_time": "1160 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to entangle all qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 2, "result": "DLE", "execution_time": "1687 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to entangle all qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    qc.x(range(n))    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 3, "result": "WA", "execution_time": "1145 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    \n    qc.mcx(list(range(n-1)), n-1)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 4, "result": "WA", "execution_time": "1413 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply a multi-controlled X gate\n    qc.mcx(list(range(n-1)), n-1)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 5, "result": "WA", "execution_time": "1176 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply a multi-controlled Z gate to flip the phase of |1...1⟩\n    if n > 1:\n        qc.mcx(list(range(n-1)), n-1)  # Apply X gate controlled by all but the last qubit\n        qc.z(n-1)  # Apply Z gate to the last qubit (which is flipped by MCX)\n        qc.mcx(list(range(n-1)), n-1)  \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 6, "result": "RE", "execution_time": "1099 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    # Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply a phase shift to all qubits\n    for i in range(n):\n        qc.u1(math.pi, i)\n    \n    # Apply Hadamard gates to all qubits again\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 7, "result": "RE", "execution_time": "1093 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    # Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply a phase shift to all qubits\n    for i in range(n):\n        qc.u1(math.pi, i)\n    \n    # Apply Hadamard gates to all qubits again\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 8, "result": "DLE", "execution_time": "1629 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 9, "result": "DLE", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, min(n, 10)):  # Limit number of CNOT gates to avoid depth issues\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC44C1006634B", "submission_order": 10, "result": "DLE", "execution_time": "1281 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n > 0:\n        qc.h(0)          # Apply Hadamard gate to the first qubit\n    \n    if n > 1:\n        for i in range(1, n):\n            qc.cx(0, i)  # Apply CNOT gates with the first qubit as control\n    \n    if n > 0:\n        qc.z(0)  \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n-)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 2, "result": "DLE", "execution_time": "1584 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 3, "result": "RE", "execution_time": "1436 ms", "memory": "140 MiB", "code": "'''python\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n\n    # すべての制御Xゲートを並列に実行\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    # 並列に Z ゲートを適用する\n    qc.z(0)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 4, "result": "WA", "execution_time": "1200 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n\n    # すべての制御Xゲートを並列に実行\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    # 並列に Z ゲートを適用する\n    qc.z(0)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 5, "result": "WA", "execution_time": "1301 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    \n    # 偶数と奇数の処理\n    for i in range(1, n, 2):  # 1つ飛ばしで偶数インデックスに対してCXを適用\n        qc.cx(i - 1, i)\n    \n    if n % 2 == 1:  # 奇数の場合、最後の量子ビットもペアリング\n        qc.cx(n - 2, n - 1)\n    \n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 6, "result": "RE", "execution_time": "1106 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_bell_state(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # 1つ目の量子ビットにハダマードゲートを適用\n    qc.h(0)\n    \n    # CNOTゲートを順次適用して、エンタングルメントを作成\n    for i in range(1, n):\n        qc.cx(i-1, i)\n    \n    # 最後に、Zゲートを適用して位相反転を行う\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 7, "result": "RE", "execution_time": "1088 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_bell_state(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n        \n    for i in range(1, n, 2):\n        qc.h(i - 1)\n        qc.cx(i - 1, i)\n    \n    if n % 2 == 1:\n        qc.h(n - 2)\n        qc.cx(n - 2, n - 1)\n    \n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 8, "result": "RE", "execution_time": "1551 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_entangled_state(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # 最初の量子ビットにハダマードゲートを適用\n    qc.h(0)\n    \n    # 1つ目と2つ目の量子ビット間にCXゲートを適用\n    qc.cx(0, 1)\n    \n    # 2つ目以降を並列化してCXゲートを適用\n    for i in range(2, n):\n        qc.cx(1, i)\n    \n    # 最後に、Zゲートを適用して |111...1> の振幅を -1 にする\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 9, "result": "RE", "execution_time": "1435 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_fully_parallel_entangled_state(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # 量子ビット0にハダマードゲートを適用\n    qc.h(0)\n    \n    # 最初の量子ビット0と1の間にCXゲートを適用\n    qc.cx(0, 1)\n    \n    # 2つ目の量子ビットを制御ビットとして、他の量子ビットにCXゲートを並列に適用\n    for i in range(2, n, 2):\n        qc.cx(1, i)\n        if i + 1 < n:\n            qc.cx(1, i + 1)\n    \n    # さらに並列化: 2段階目の並列化 (この例では、3と4に並列に適用)\n    for i in range(3, n, 2):\n        if i + 1 < n:\n            qc.cx(2, i + 1)\n\n    # 最後に、Zゲートを適用して |111...1> の振幅を -1 にする\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 10, "result": "RE", "execution_time": "1121 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef create_entangled_state_with_mcx(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # 最初の量子ビットにハダマードゲートを適用\n    qc.h(0)\n    \n    # 多重制御CXゲートを適用して、全ての量子ビットをエンタングルメント\n    if n > 2:\n        mcx_gate = MCXGate(num_ctrl_qubits=n-2)\n        qc.append(mcx_gate, [i for i in range(n)])\n    else:\n        qc.cx(0, 1)\n    \n    # 最後に、Zゲートを適用して |111...1> の振幅を -1 にする\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 11, "result": "RE", "execution_time": "1384 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_entangled_state_with_mcx(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: 1から n % 2 個目までの量子ビットに H ゲートを適用\n    for i in range(0, n % 2):\n        qc.h(i)\n    \n    # Step 2: 1個目と n % 2 + 1 個目の量子ビットに CX ゲートを適用\n    for i in range(0, n - 1, 2):\n        if i + (n % 2) < n:\n            qc.cx(i, i + (n % 2))\n\n    return qc\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 12, "result": "RE", "execution_time": "1452 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef create_entangled_state_with_mcx(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0, n % 2):\n        qc.h(i)\n    \n    for i in range(0, n % 2 + 1):\n        qc.cx(i, i + (n % 2 + 1))\n\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 13, "result": "RE", "execution_time": "1350 ms", "memory": "141 MiB", "code": "'''python\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(0, n, 2):\n        qc.h(i)\n\n    # 偶数と奇数の処理\n    for i in range(1, n, 2):  # 1つ飛ばしで偶数インデックスに対してCXを適用\n        qc.cx(i - 1, i)\n    \n    if n % 2 == 1:  # 奇数の場合、最後の量子ビットもペアリング\n        qc.cx(n - 2, n - 1)\n    \n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 14, "result": "WA", "execution_time": "1649 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(0, n, 2):\n        qc.h(i)\n\n    # 偶数と奇数の処理\n    for i in range(1, n, 2):  # 1つ飛ばしで偶数インデックスに対してCXを適用\n        qc.cx(i - 1, i)\n    \n    if n % 2 == 1:  # 奇数の場合、最後の量子ビットもペアリング\n        qc.cx(n - 2, n - 1)\n    \n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC4D35B2115DB", "submission_order": 15, "result": "WA", "execution_time": "1416 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(0, n, 2):\n        qc.h(i)\n\n    # 偶数と奇数の処理\n    for i in range(1, n, 2):  # 1つ飛ばしで偶数インデックスに対してCXを適用\n        qc.cx(i - 1, i)\n        qc.z(i)\n\n    if n % 2 == 1:  # 奇数の場合、最後の量子ビットもペアリング\n        qc.cx(n - 2, n - 1)\n        qc.z(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC78BC07966DB", "submission_order": 1, "result": "DLE", "execution_time": "1150 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,range(1,n))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC78BC07966DB", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble\nfrom qiskit.visualization import plot_histogram\n\ndef create_state_psi(n):\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply multi-controlled Z gate (with global phase change ignored)\n    if n > 1:\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)  # multi-controlled X (CNOT with (n-1) controls)\n        qc.h(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 1, "result": "WA", "execution_time": "1202 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOTs in a balanced tree structure\n    for layer in range(1, (n-1).bit_length()):\n        for i in range(1 << (layer - 1), min(1 << layer, n)):\n            qc.cx(i - (1 << (layer - 1)), i)\n    \n    # Apply Z gate to the first qubit to introduce the minus sign\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 2, "result": "WA", "execution_time": "1640 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gates to create the entanglement\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Apply X gate to all qubits to flip the sign of |1...1⟩ state\n    for i in range(n):\n        qc.x(i)\n    \n    # Apply Hadamard gate to the first qubit again\n    qc.h(0)\n    \n    # Apply CNOT gates again to disentangle\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 3, "result": "RE", "execution_time": "1119 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply n-controlled Z gate\n    qc.mcz(list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 4, "result": "RE", "execution_time": "1158 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply n-controlled Z gate\n    qc.mcz(list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 5, "result": "RE", "execution_time": "1292 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply n-controlled Z gate\n    qc.mcz(list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 6, "result": "RE", "execution_time": "1387 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply n-controlled Z gate\n    qc.mcz(list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 7, "result": "WA", "execution_time": "1199 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to all qubits\n    qc.h(range(n))\n    \n    # Apply CNOT gates to create the state |ψ⟩\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    \n    # Apply a Z gate to the last qubit to get the correct sign\n    qc.z(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 8, "result": "WA", "execution_time": "1171 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply controlled-Z gates to create the state\n    for i in range(n - 1):\n        qc.cz(i, i + 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 9, "result": "WA", "execution_time": "1547 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to each qubit\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply controlled-Z gates between each pair of qubits\n    for i in range(n):\n        for j in range(i + 1, n):\n            qc.cz(i, j)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 10, "result": "DLE", "execution_time": "1444 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gates to create entanglement\n    for qubit in range(n - 1):\n        qc.cx(qubit, qubit + 1)\n    \n    # Apply a phase shift to the last qubit\n    qc.z(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 11, "result": "WA", "execution_time": "1187 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply controlled-Z gates between adjacent qubits\n    for qubit in range(n - 1):\n        qc.cz(qubit, qubit + 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AC7F28E1B5454", "submission_order": 12, "result": "WA", "execution_time": "1775 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gates in a chain\n    for qubit in range(n - 1):\n        qc.cx(qubit, qubit + 1)\n    \n    # Apply a phase flip to all qubits (except the first) to get the negative sign\n    for qubit in range(1, n):\n        qc.z(qubit)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ACAB71FDB4892", "submission_order": 1, "result": "WA", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # finding the mid qubit\n\n    m = int(n/2)\n    for i in range(m):\n        qc.cx(0,m-i)\n        if i > 0:\n            qc.cx(m,m+i)\n        \n    if n%2 != 0:\n        qc.cx(0,n-1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ACAB71FDB4892", "submission_order": 2, "result": "AC", "execution_time": "2440 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    # finding the mid qubit\n\n    m = int(n/2)\n    for i in range(m):\n        qc.cx(0,m-i)\n        if i > 0:\n            qc.cx(m,m+i)\n        \n    if n%2 != 0:\n        qc.cx(0,n-1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ACD61AD8E3AE2", "submission_order": 1, "result": "WA", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(0, n-1)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ACD61AD8E3AE2", "submission_order": 2, "result": "WA", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, n-1)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD0497D19273A", "submission_order": 1, "result": "AC", "execution_time": "2193 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        j = (1<<(i.bit_length()-1))\n        qc.cx(i-j,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD0B3D5874C54", "submission_order": 1, "result": "DLE", "execution_time": "1460 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if i==0:\n            continue\n        else:\n            qc.cx(0,i)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD0B3D5874C54", "submission_order": 2, "result": "AC", "execution_time": "1756 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.h(0)\n    qc.cx(0, 1)\n \n    for i in range(2, n - 1, 2):\n        qc.cx(0, i)\n        qc.cx(1, i + 1)\n \n    if n % 2 != 0:\n        qc.cx(0, n - 1)\n \n    qc.z(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD3B3478C5A2E", "submission_order": 1, "result": "DLE", "execution_time": "1439 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(n-1):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD3B3478C5A2E", "submission_order": 2, "result": "AC", "execution_time": "2156 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n \n    for i in range(2, n - 1, 2):\n        qc.cx(0, i)\n        qc.cx(1, i + 1)\n \n    if n % 2 != 0:\n        qc.cx(0, n - 1)\n \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD444BF25B084", "submission_order": 1, "result": "AC", "execution_time": "2741 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    circuitEnd = False\n    for i in [int(pow(2, x)) for x in range(0, 4)]:\n\n        for j in range(i):\n            if (j + i >= n):\n                circuitEnd = True\n                break\n            qc.cx(j, j + i)\n        if (circuitEnd):\n            break\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 1, "result": "WA", "execution_time": "1187 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for i in range(2,n):\n        qc.cx(0,i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n   qc.h(0)\n    \n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n   qc.h(0)\n    \n    for i in range(2, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 4, "result": "WA", "execution_time": "1519 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 5, "result": "DLE", "execution_time": "1043 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 6, "result": "RE", "execution_time": "1301 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n > 1:\n        qc.append(MCXGate(n-1), range(1, n))\n\n\n\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n > 1:\n    for i in range(1, n):\n            qc.cx(0, i)\n\n\n\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 8, "result": "DLE", "execution_time": "1496 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n > 1:\n        for i in range(1, n):\n            qc.cx(0, i)\n\n\n\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 9, "result": "RE", "execution_time": "1173 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n > 1:\n        for i in range(1, n):\n            qc.cx(0, i)\n\n    optimized_qc = transpile(qc, optimization_level=3)\n\n\n\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD50246C3797E", "submission_order": 10, "result": "RE", "execution_time": "1164 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n > 1:\n        for i in range(1, n):\n            qc.cx(0, i)\n\n    optimized_qc = transpile(qc, optimization_level=10)\n\n\n\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD574EFBD2008", "submission_order": 1, "result": "RE", "execution_time": "1488 ms", "memory": "140 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-math.pi, 0)\n\n    for i in range(2, N + 1):\n        qc.cx(i // 2 - 1, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD574EFBD2008", "submission_order": 2, "result": "WA", "execution_time": "1233 ms", "memory": "140 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-math.pi, 0)\n    \n    log = int(math.log2(n - 1)) + 1\n\n    swapped = [False] * n\n    swapped[0] = True\n\n    for i in range(log - 1, -1, -1):\n        for j in range(n):\n            if not swapped[j]:\n                continue\n\n            next_j = j * 2**i\n            if next_j < n and not swapped[next_j]:\n                swapped[next_j] = True\n                qc.cx(j, next_j)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD574EFBD2008", "submission_order": 3, "result": "WA", "execution_time": "1669 ms", "memory": "141 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-math.pi, 0)\n    \n    log = int(math.log2(n)) + 1\n\n    swapped = [False] * n\n    swapped[0] = True\n\n    for i in range(log - 1, -1, -1):\n        for j in range(n):\n            if not swapped[j]:\n                continue\n\n            next_j = j * 2**i\n            if next_j < n and not swapped[next_j]:\n                swapped[next_j] = True\n                qc.cx(j, next_j)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD574EFBD2008", "submission_order": 4, "result": "AC", "execution_time": "2119 ms", "memory": "143 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-math.pi, 0)\n\n    log = int(math.log2(n - 1)) + 1\n\n    swapped = set([0])\n\n    for i in range(log - 1, -1, -1):\n        done = set()\n        for j in range(n):\n            if j not in swapped:\n                continue\n\n            next_j = j + 2**i\n            print(j, next_j)\n            if next_j < n and next_j not in swapped:\n                done.add(next_j)\n                qc.cx(j, next_j)\n        swapped |= done\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD6C962E51626", "submission_order": 1, "result": "AC", "execution_time": "2290 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    for i in range(1, n, 2):\n        qc.cx(0, i)\n        if i+1 < n:\n            qc.cx(i, i+1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD7507A7503B1", "submission_order": 1, "result": "WA", "execution_time": "2017 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(n-1):\n        if i % 2 == 0:\n            qc.cx(1, i)\n        if i % 2 == 1:\n            qc.cx(0, i)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD7507A7503B1", "submission_order": 2, "result": "WA", "execution_time": "1950 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(n-1):\n        if i % 2 == 0:\n            qc.cx(1, i)\n        if i % 2 == 1:\n            qc.cx(0, i)\n    qc.z(0)    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD7507A7503B1", "submission_order": 3, "result": "WA", "execution_time": "1869 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(n-1):\n        if i % 2 == 0:\n            qc.cx(1, i)\n        if i % 2 == 1:\n            qc.cx(0, i)\n    qc.z(1)    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD7507A7503B1", "submission_order": 4, "result": "RE", "execution_time": "1701 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n):\n        if i % 2 == 0:\n            qc.cx(0, i)\n        if i % 2 == 1:\n            qc.cx(1, i)\n    qc.z(0)    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD7507A7503B1", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-1):\n        if i % 2 == 0:\n            qc.cx(0, i+1)\n        if i % 2 == 1:\n            qc.cx(, i+1)\n    qc.z(0)    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AD7507A7503B1", "submission_order": 6, "result": "AC", "execution_time": "2213 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-1):\n        if i % 2 == 0:\n            qc.cx(0, i+1)\n        if i % 2 == 1:\n            qc.cx(1, i+1)\n    qc.z(0)    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADA4252D6054C", "submission_order": 1, "result": "WA", "execution_time": "1109 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qbit_list = list(range(1, n, 1))\n    done_list = [0]\n    is_done = False\n    while(True):\n\n        doing_list = []\n        for c in done_list:\n            if len(qbit_list)==0:\n                is_done = True\n                break\n            target = qbit_list.pop(0)\n            qc.cx(c, target)\n            doing_list.append(target)\n\n        if is_done:\n            break\n        done_list.extend(doing_list)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADA4252D6054C", "submission_order": 2, "result": "AC", "execution_time": "1973 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qbit_list = list(range(1, n, 1))\n    done_list = [0]\n    is_done = False\n    while(True):\n\n        doing_list = []\n        for c in done_list:\n            if len(qbit_list)==0:\n                is_done = True\n                break\n            target = qbit_list.pop(0)\n            qc.cx(c, target)\n            doing_list.append(target)\n\n        if is_done:\n            break\n        done_list.extend(doing_list)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADBCE4C243976", "submission_order": 1, "result": "AC", "execution_time": "2256 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i//2, i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 1, "result": "RE", "execution_time": "1806 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        qc.cx(0, n)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 2, "result": "RE", "execution_time": "1173 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if i == 0:\n            continue\n        qc.cx(0, n)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 3, "result": "RE", "execution_time": "1088 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if i == 0:\n            continue\n        qc.cx(0, n)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 4, "result": "WA", "execution_time": "1571 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if i == 0:\n            continue\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 5, "result": "WA", "execution_time": "1560 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 6, "result": "WA", "execution_time": "1062 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef entangle_pairs(qc, qubits):\n    for i in range(0, len(qubits) - 1, 2):\n        qc.cx(qubits[i], qubits[i + 1])\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) <= 1:\n        return\n    entangle_pairs(qc, qubits)\n    next_level = [qubits[i] for i in range(0, len(qubits), 2)]\n    entangle_tree(qc, next_level)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    entangle_tree(qc, list(range(n)))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 7, "result": "WA", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef entangle_pairs(qc, qubits):\n    for i in range(0, len(qubits) - 1, 2):\n        qc.cx(qubits[i], qubits[i + 1])\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) <= 1:\n        return\n    entangle_pairs(qc, qubits)\n    next_level = [qubits[i] for i in range(0, len(qubits), 2)]\n    entangle_tree(qc, next_level)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n\n    entangle_tree(qc, list(range(1, n)))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 8, "result": "DLE", "execution_time": "1133 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 9, "result": "WA", "execution_time": "2377 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef entangle_pairs(qc, qubits):\n    \"\"\"ペアごとにエンタングルメントを行う\"\"\"\n    for i in range(0, len(qubits) - 1, 2):\n        qc.cx(qubits[i], qubits[i + 1])\n\ndef entangle_tree(qc, qubits):\n    \"\"\"ツリー状にエンタングルメントを行う\"\"\"\n    if len(qubits) <= 1:\n        return\n    entangle_pairs(qc, qubits)\n    # 次のレベルの代表量子ビットを選択\n    next_level = [qubits[i] for i in range(0, len(qubits), 2)]\n    entangle_tree(qc, next_level)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 量子ビット0を重ね合わせ状態にする\n    qc.h(0)\n    # 全ての量子ビットをツリー状にエンタングルメントする\n    entangle_tree(qc, list(range(n)))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 10, "result": "RE", "execution_time": "1086 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef split_list(lst):\n    mid = len(lst) // 2\n    return lst[:mid], lst[mid:]\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) == 1:\n        return qubits[0]\n    elif len(qubits) == 2:\n        qc.cx(qubits[0], qubits[1])\n        return qubits[0]\n    elif len(qubits) >= 3:\n        left, right = split_list(qubits)\n        return entangle_tree([entangle_tree(qc, left), entangle_tree(qc, right)])\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    entangle_tree(qc, list(range(n)))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 11, "result": "WA", "execution_time": "1185 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef split_list(lst):\n    mid = len(lst) // 2\n    return lst[:mid], lst[mid:]\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) == 1:\n        return qubits[0]\n    elif len(qubits) == 2:\n        qc.cx(qubits[0], qubits[1])\n        return qubits[0]\n    elif len(qubits) >= 3:\n        left, right = split_list(qubits)\n        return entangle_tree(qc, [entangle_tree(qc, left), entangle_tree(qc, right)])\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    entangle_tree(qc, list(range(n)))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 12, "result": "WA", "execution_time": "1248 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef split_list(lst):\n    mid = len(lst) // 2\n    return lst[:mid], lst[mid:]\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) == 1:\n        return qubits[0]\n    elif len(qubits) == 2:\n        qc.cx(qubits[0], qubits[1])\n        return qubits[0]\n    elif len(qubits) >= 3:\n        left, right = split_list(qubits)\n        return entangle_tree(qc, [entangle_tree(qc, left), entangle_tree(qc, right)])\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, entangle_tree(qc, list(range(1, n))))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 13, "result": "WA", "execution_time": "1713 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef split_list(lst):\n    mid = len(lst) // 2\n    return lst[:mid], lst[mid:]\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) == 1:\n        return qubits[0]\n    elif len(qubits) == 2:\n        qc.cx(qubits[0], qubits[1])\n        return qubits[0]\n    elif len(qubits) >= 3:\n        left, right = split_list(qubits)\n        return entangle_tree(qc, [entangle_tree(qc, left), entangle_tree(qc, right)])\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(0, entangle_tree(qc, list(range(1, n))))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 14, "result": "WA", "execution_time": "1086 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef split_list(lst):\n    mid = len(lst) // 2\n    return lst[:mid], lst[mid:]\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) == 1:\n        return qubits[0]\n    elif len(qubits) == 2:\n        qc.cx(qubits[0], qubits[1])\n        return qubits[0]\n    elif len(qubits) >= 3:\n        left, right = split_list(qubits)\n        return entangle_tree(qc, [entangle_tree(qc, left), entangle_tree(qc, right)])\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, entangle_tree(qc, list(range(1, n))))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 15, "result": "WA", "execution_time": "1519 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef split_list(lst):\n    mid = len(lst) // 2\n    return lst[:mid], lst[mid:]\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) == 1:\n        return qubits[0]\n    elif len(qubits) == 2:\n        qc.cx(qubits[0], qubits[1])\n        return qubits[0]\n    elif len(qubits) >= 3:\n        left, right = split_list(qubits)\n        return entangle_tree(qc, [entangle_tree(qc, left), entangle_tree(qc, right)])\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, entangle_tree(qc, list(range(1, n))))\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE31A76CB302", "submission_order": 16, "result": "WA", "execution_time": "1418 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef split_list(lst):\n    mid = len(lst) // 2\n    return lst[:mid], lst[mid:]\n\ndef entangle_tree(qc, qubits):\n    if len(qubits) == 1:\n        return qubits[0]\n    elif len(qubits) == 2:\n        qc.cx(qubits[0], qubits[1])\n        return qubits[0]\n    elif len(qubits) >= 3:\n        left, right = split_list(qubits)\n        return entangle_tree(qc, [entangle_tree(qc, left), entangle_tree(qc, right)])\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    entangle_tree(qc, list(range(1, n)))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE5459D072BE", "submission_order": 1, "result": "DLE", "execution_time": "1248 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE5459D072BE", "submission_order": 2, "result": "DLE", "execution_time": "1268 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to the first qubit to create superposition\n    qc.h(0)\n    \n    # Apply CNOT gates to entangle the qubits\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    \n    # Add a Z gate to the last qubit to ensure the correct phase\n    qc.z(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE5459D072BE", "submission_order": 3, "result": "WA", "execution_time": "1712 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply CNOT gates to entangle the qubits\n    # Use a sequence that allows for parallel gate applications\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    \n    # Apply X gate to the last qubit to adjust the phase\n    qc.x(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE5459D072BE", "submission_order": 4, "result": "WA", "execution_time": "1317 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    qc.h(range(n))\n    \n    # Apply multi-controlled phase gate\n    # The phase θ = π to achieve the desired state\n    theta = np.pi\n    # Create a multi-controlled phase gate\n    if n > 1:\n        qc.append(MCPhaseGate(theta, n - 1), range(n))\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE835C548ACC", "submission_order": 1, "result": "RE", "execution_time": "1066 ms", "memory": "140 MiB", "code": "'''python\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE835C548ACC", "submission_order": 2, "result": "DLE", "execution_time": "1373 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE835C548ACC", "submission_order": 3, "result": "WA", "execution_time": "1069 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(1, n):\n        if i % 2 == 1:\n            qc.cx(0, i)\n        else:\n            qc.cx(1, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADE835C548ACC", "submission_order": 4, "result": "AC", "execution_time": "1838 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, n):\n        if i % 2 == 1:\n            qc.cx(0, i)\n        else:\n            qc.cx(1, i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADEEE840EA982", "submission_order": 1, "result": "WA", "execution_time": "1103 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    step = 1\n    while step < n:\n        for i in range(0, n - step, step * 2):\n            qc.cx(i, i + step)\n        step *= 2\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADEEE840EA982", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    ans = [0 for _ in range(n)]\n    qc.cx(0, n//2)\n    ans[0] = 1\n    ans[n//2] = 1\n    r = (n//2)//2\n    while not all(ans):\n        for i in range(n-r):\n            if ans[i] == 1 and ans[i+r] == 0:\n                qc.cx(i, i+r)\n                ans[i+r] = 1\n        r //= 2\n    qc.z(0)\n    return qc\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADEEE840EA982", "submission_order": 3, "result": "TLE", "execution_time": "3000 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    ans = [0 for _ in range(n)]\n    qc.cx(0, n//2)\n    ans[0] = 1\n    ans[n//2] = 1\n    r = (n//2)//2\n    while not all(ans):\n        for i in range(n-r):\n            if ans[i] == 1 and ans[i+r] == 0:\n                qc.cx(i, i+r)\n                ans[i+r] = 1\n        r //= 2\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "ADEEE840EA982", "submission_order": 4, "result": "AC", "execution_time": "2105 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    if n == 3:\n        return solve3()\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    ans = [0 for _ in range(n)]\n    qc.cx(0, n//2)\n    ans[0] = 1\n    ans[n//2] = 1\n    r = (n//2)//2\n    while not all(ans):\n        for i in range(n-r):\n            if ans[i] == 1 and ans[i+r] == 0:\n                qc.cx(i, i+r)\n                ans[i+r] = 1\n        if r != 1:\n            r //= 2\n        else:\n            break\n    qc.z(0)\n    return qc\n\ndef solve3():\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, 3):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AE4980A05EC38", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m = 0\n    qc.h(0)\n    for i in range(5):\n        for l in range(i):\n            qc.cx(l,l+i+1)\n            if l+i+1 > n:\n                m = 1\n                break\n        if m = 1:\n            break\n    qc.z(0)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AE4980A05EC38", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m = 0\n    qc.h(0)\n    for i in range(5):\n        for l in range(i+1):\n            qc.cx(l,l+i+1)\n            if l+i+1 => n:\n                m = 1\n                break\n        if m = 1:\n            break\n    qc.z(0)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AE4980A05EC38", "submission_order": 3, "result": "AC", "execution_time": "2209 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m = 1\n    qc.h(0)\n    for i in range(5):\n        for l in range(i+1):\n            if m >= n:\n                break\n            qc.cx(l,m)\n            m += 1\n        if m >= n:\n            break\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AE50A4A912A91", "submission_order": 1, "result": "AC", "execution_time": "1832 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.z(0)\n    for w in range(4):\n        w = 1 << w\n        for i in range(w, w << 1):\n            if i < n:\n                qc.cx(i - w, i)\n \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AE6D7BAEEC523", "submission_order": 1, "result": "AC", "execution_time": "2166 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    if(n>2):\n        qc.cx(0, 2)\n    if(n>3):\n        qc.cx(1, 3)\n    if(n>4):\n        qc.cx(0, 4)\n    if(n>5):\n        qc.cx(1, 5)\n    if(n>6):\n        qc.cx(2, 6)\n    if(n>7):\n        qc.cx(3, 7)\n    if(n>8):\n        qc.cx(0, 8)\n    if(n>9):\n        qc.cx(1, 9)\n    if(n>10):\n        qc.cx(2, 10)\n    if(n>11):\n        qc.cx(3, 11)\n    if(n>12):\n        qc.cx(4, 12)\n    if(n>13):\n        qc.cx(5, 13)\n    if(n>14):\n        qc.cx(6, 14)\n    \n    qc.crz(2*math.pi, 0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AE9F7F939BF95", "submission_order": 1, "result": "AC", "execution_time": "1817 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n#from qiskit.quantum_info import Statevector\n\n\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(1,4):\n        for j in range(1,2**i+1):\n            ind = 2**i + j - 1\n            if ind >= n:\n                break\n            qc.cx(ind-2**i,ind)\n    qc.cp(np.pi,0,n-1)\n    return qc\n\nqc = solve(5)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 1, "result": "DLE", "execution_time": "1167 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 2, "result": "DLE", "execution_time": "1157 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n//2+1):\n        qc.cx(0,i)\n    for i in range(n//2+1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 3, "result": "WA", "execution_time": "1264 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n//2+1):\n        qc.cx(0,i)\n    for i in range(n//2+2,n):\n        qc.cx(n//2+1,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 4, "result": "DLE", "execution_time": "1146 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n//2+1):\n        qc.cx(0,i)\n    for i in range(n//2+1,n):\n        qc.cx(0,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 5, "result": "WA", "execution_time": "1284 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, n, 2):\n        if i + 1 < n:\n            qc.cx(i, i + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 6, "result": "DLE", "execution_time": "1616 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(1,n-1):\n            qc.cx(i, i + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 7, "result": "RE", "execution_time": "1152 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,n,2):\n        qc.h(i)\n        qc.cx(i,i+1)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 8, "result": "RE", "execution_time": "1145 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc.h(0)\n    \n    step = 1\n    while step < n:\n        for i in range(step, n, 2*step):\n            qc.cx(0, i)\n        step *= 2\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 9, "result": "DLE", "execution_time": "1162 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    \n    step = 1\n    while step < n:\n        for i in range(step, n, 2*step):\n            qc.cx(0, i)\n        step *= 2\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 10, "result": "RE", "execution_time": "1176 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n\n    for i in range(n):\n        qc.p(-3.141592653589793, i)\n\n    qc.append(QFT(num_qubits=n, inverse=True), range(n))        \n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 11, "result": "RE", "execution_time": "1070 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n//2+1):\n        qc.cx(0,i)\n    for i in range(n//2+1):\n        qc.cx(i,i+n//2)\n    if(n%2==1):\n        qc.cx(0,n)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEAE14E6F607C", "submission_order": 12, "result": "AC", "execution_time": "2403 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n//2):\n        qc.cx(0,i)\n    for i in range(n//2):\n        qc.cx(i,i+n//2)\n    if(n%2==1):\n        qc.cx(0,n-1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AECCFACB117EF", "submission_order": 1, "result": "DLE", "execution_time": "1532 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AECCFACB117EF", "submission_order": 2, "result": "DLE", "execution_time": "1176 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AECCFACB117EF", "submission_order": 3, "result": "DLE", "execution_time": "1214 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AECCFACB117EF", "submission_order": 4, "result": "WA", "execution_time": "1082 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AECCFACB117EF", "submission_order": 5, "result": "WA", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AECCFACB117EF", "submission_order": 6, "result": "DLE", "execution_time": "1154 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.z(n-1)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AECCFACB117EF", "submission_order": 7, "result": "WA", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.x(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AECCFACB117EF", "submission_order": 8, "result": "WA", "execution_time": "1397 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(range(n))\n    qc.z(n-1)\n    qc.h(range(n))\n\n    \n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AED53BD75897E", "submission_order": 1, "result": "DLE", "execution_time": "1196 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AED53BD75897E", "submission_order": 2, "result": "DLE", "execution_time": "1181 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AED53BD75897E", "submission_order": 3, "result": "WA", "execution_time": "1162 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cz(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AED53BD75897E", "submission_order": 4, "result": "WA", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    for i in range(n - 1):\n        qc.cz(i, n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AED53BD75897E", "submission_order": 5, "result": "DLE", "execution_time": "1240 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.h(i)\n    qc.x(n - 1)\n    \n    for i in range(n - 1):\n        qc.cx(i, n - 1)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AED53BD75897E", "submission_order": 6, "result": "AC", "execution_time": "2880 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(i // 2, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEFA450355619", "submission_order": 1, "result": "DLE", "execution_time": "1390 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        # entangle the states using cnot with 0 qubit as control\n        qc.cx(0, i)\n    # use z gate to phase flip the highest state\n    qc.z(0)    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEFA450355619", "submission_order": 2, "result": "RE", "execution_time": "1372 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        # entangle the states using cnot with 0 qubit as control\n        qc.cx(0, i)\n    # use z gate to phase flip the highest state but use cz to decrease depth\n    qc.cz(0)    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEFA450355619", "submission_order": 3, "result": "DLE", "execution_time": "1418 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        # entangle the states using cnot with 0 qubit as control\n        qc.cx(0, i)\n    # use z gate to phase flip the highest state but use cz to decrease dept\n    qc.cz(0, n-1)    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEFA450355619", "submission_order": 4, "result": "RE", "execution_time": "1448 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        # entangle the states using cnot with 0 qubit as control\n        qc.cnot(0, i)\n    # use z gate to phase flip the highest state but use cz to decrease dept\n    qc.cz(0, n-1)    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEFFE50ED2ECC", "submission_order": 1, "result": "DLE", "execution_time": "1524 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    qc.cx(0, range(1, n))\n\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AEFFE50ED2ECC", "submission_order": 2, "result": "AC", "execution_time": "2088 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx(i//2, i)\n\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AF11F56825EA6", "submission_order": 1, "result": "DLE", "execution_time": "1812 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for _ in range(1,n):\n        qc.cx(0,_)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AF11F56825EA6", "submission_order": 2, "result": "WA", "execution_time": "1761 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    for i in range(1,(n - 1) // 2):\n        qc.cx(0,i * 2)\n        qc.cx(1,i * 2 + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AF11F56825EA6", "submission_order": 3, "result": "WA", "execution_time": "1753 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(1,(n - 1) // 2):\n        qc.cx(0,i * 2)\n        qc.cx(1,i * 2 + 1)\n    if n % 2 == 1:\n        qc.cx(0,n - 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AF11F56825EA6", "submission_order": 4, "result": "AC", "execution_time": "2150 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(1,n // 2):\n        qc.cx(0,i * 2)\n        qc.cx(1,i * 2 + 1)\n    if n % 2 == 1:\n        qc.cx(0,n - 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AF4198C186231", "submission_order": 1, "result": "DLE", "execution_time": "1368 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AF7B7889E5503", "submission_order": 1, "result": "DLE", "execution_time": "1636 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AF7B7889E5503", "submission_order": 2, "result": "AC", "execution_time": "2035 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n# Apply a series of CNOT gates\n    for i in range(n - 1):\n        if i + 2 < n:\n            qc.cx(i, i + 2)\n        else:\n            pass\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFB638952CBFC", "submission_order": 1, "result": "DLE", "execution_time": "1168 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, range(1, n))\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFB638952CBFC", "submission_order": 2, "result": "WA", "execution_time": "1547 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for d in range(1, n):\n        for i in range(n):\n            if i + d < n:\n                qc.cx(i, i + d)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFB638952CBFC", "submission_order": 3, "result": "AC", "execution_time": "2792 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    d = 1\n    while d < n:\n        for i in range(0, d):\n            if i + d < n:\n                qc.cx(i, i + d)\n                print(i, i + d)\n        d *= 2\n    qc.z(0)\n\n    return qc\n\n# solve(15).draw('mpl').show()\n'''"}
{"problem": "QPC002_A4", "user": "AFD9C3A68358D", "submission_order": 1, "result": "DLE", "execution_time": "1310 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0,i)\n\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 1, "result": "DLE", "execution_time": "1219 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates from the first qubit to each of the other qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 2, "result": "QLE", "execution_time": "1273 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(4)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates from the first qubit to each of the other qubits\n    for i in range(1, 4):\n        qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 3, "result": "QLE", "execution_time": "1315 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates from the first qubit to each of the other qubits\n    for i in range(1, 3):\n        qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 4, "result": "DLE", "execution_time": "1215 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n     # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gates from the first qubit to each of the other qubits in parallel\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 5, "result": "DLE", "execution_time": "1196 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates between the first qubit and each of the other qubits\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 6, "result": "RE", "execution_time": "1312 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    qc.cx(0, 3)\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 7, "result": "RE", "execution_time": "1353 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    qc.cx(0, 3)\n    qc.cx(0, 4)\n\n    \n    # Step 3: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 8, "result": "DLE", "execution_time": "1367 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n        \n    # Step 2: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    # Step 3: Apply a final CNOT gate between the first qubit and all others\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 9, "result": "WA", "execution_time": "1297 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n        \n    # Step 2: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    # Step 3: Apply a final CNOT gate between the first qubit and all others\n    for i in range(1, n-1):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 10, "result": "DLE", "execution_time": "1148 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 3: Apply a final CNOT gate between the first qubit and all others\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    # Step 2: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 11, "result": "WA", "execution_time": "1359 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply X gate to all qubits (to prepare for the MCZ)\n    for i in range(n):\n        qc.x(i)\n    \n    # Step 3: Apply a multi-controlled Z (MCZ) gate\n    qc.h(n-1)  # Convert Z to X (as multi-controlled X is easier)\n    qc.mcx(list(range(n-1)), n-1)  # Apply the multi-controlled X\n    qc.h(n-1)  # Convert X back to Z\n\n    # Step 4: Apply X gate again to all qubits\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 12, "result": "WA", "execution_time": "1359 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply an X gate to the last qubit to ensure Z gate impacts the correct state\n    qc.x(n-1)\n\n    # Step 3: Apply Controlled-Z gate between first qubit and the last one\n    qc.cz(0, n-1)\n\n    # Step 4: Apply X gate to revert the last qubit to its original state\n    qc.x(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 13, "result": "WA", "execution_time": "1123 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply an n-qubit controlled-Z gate (multi-controlled Z)\n    # Convert Z to X (since multi-controlled X is easier to apply)\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)  # Multi-controlled X\n    qc.h(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 14, "result": "DLE", "execution_time": "1143 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to entangle the first qubit with all others\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply a Z gate to introduce the phase of -1\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 15, "result": "WA", "execution_time": "1198 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1: Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply controlled-Z gate with depth optimization\n    qc.cz(0, n-1)  # This introduces the -1 phase to the |1...1> state\n    \n    # Step 3: Apply X gates to qubits 1 to n-2 and then controlled-Z\n    for i in range(1, n-1):\n        qc.cx(i, n-1)  # Entangles qubits sequentially\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 16, "result": "DLE", "execution_time": "1667 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to entangle the first qubit with all others\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply a Z gate to introduce the phase of -1\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 17, "result": "RE", "execution_time": "1208 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in a layered manner\n    for i in range(1, n//2):\n        qc.cx(0, i)  # First half of CNOTs\n    for i in range(n//2, n):\n        qc.cx(1, i)  # Second half of CNOTs\n    \n    # Step 3: Apply a Z gate to introduce the phase of -1\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 18, "result": "RE", "execution_time": "1182 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in layers to reduce depth\n    # Layer 1\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    qc.cx(0, 4)\n    qc.cx(0, 8)\n    \n    # Layer 2\n    qc.cx(1, 3)\n    qc.cx(1, 5)\n    qc.cx(2, 6)\n    qc.cx(2, 7)\n    \n    # Layer 3\n    qc.cx(3, 9)\n    qc.cx(4, 10)\n    qc.cx(5, 11)\n    qc.cx(6, 12)\n    \n    # Step 3: Apply a Z gate to introduce the phase of -1\n    qc.z(0)\n    \n    # Step 3: Apply a Z gate to introduce the phase of -1\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 19, "result": "RE", "execution_time": "1179 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    ## Step 2: Apply CNOT gates in layers to reduce depth\n    # Layer 1: Apply CNOT from qubit 0 to qubits 1, 2, 4, 8\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    qc.cx(0, 4)\n    qc.cx(0, 8)\n    \n    # Layer 2: Apply CNOTs from qubits 1 to 3, 2 to 5, 4 to 6, 8 to 10\n    qc.cx(1, 3)\n    qc.cx(2, 5)\n    qc.cx(4, 6)\n    qc.cx(8, 10)\n    \n    # Layer 3: Apply CNOTs from qubits 3 to 7, 5 to 9, 6 to 11, 10 to 12\n    qc.cx(3, 7)\n    qc.cx(5, 9)\n    qc.cx(6, 11)\n    qc.cx(10, 12)\n    \n    # Layer 4: Apply CNOTs from qubits 7 to 13, 9 to 14\n    qc.cx(7, 13)\n    qc.cx(9, 14)\n    \n    # Step 3: Apply a Z gate to introduce the phase of -1\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 20, "result": "RE", "execution_time": "1120 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    ## Step 2: Apply CNOT gates in layers to reduce depth\n    # Layer 1: Apply CNOT from qubit 0 to qubits 1, 2, 4, 8\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    qc.cx(0, 4)\n    qc.cx(0, 8)\n    \n    # Layer 2: Apply CNOTs from qubits 1 to 3, 2 to 5, 4 to 6, 8 to 10\n    qc.cx(1, 3)\n    qc.cx(2, 5)\n    qc.cx(4, 6)\n    qc.cx(8, 10)\n    \n    # Layer 3: Apply CNOTs from qubits 3 to 7, 5 to 9, 6 to 11, 10 to 12\n    qc.cx(3, 7)\n    qc.cx(5, 9)\n    qc.cx(6, 11)\n    qc.cx(10, 12)\n    \n    # Layer 4: Apply CNOTs from qubits 7 to 13, 9 to 14\n    qc.cx(7, 13)\n    qc.cx(9, 14)\n    \n    # Step 3: Apply a Z gate to introduce the phase of -1\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 21, "result": "WA", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in a more parallelized manner\n    step = 1\n    while step < n:\n        for i in range(0, n, step * 2):\n            if i + step < n:\n                qc.cx(i, i + step)\n        step *= 2\n    \n    # Step 3: Apply a Z gate to the first qubit\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 22, "result": "WA", "execution_time": "1187 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in layers to minimize depth\n    # First layer: CNOT from qubit 0 to all qubits that are powers of 2\n    for i in range(1, n):\n        if i & (i - 1) == 0:  # This condition checks if 'i' is a power of 2\n            qc.cx(0, i)\n    \n    # Second layer: CNOT from qubits already entangled in the first layer to others\n    for i in range(1, n):\n        if i & (i - 1) != 0 and i & (n // 2) == 0:  # Skip the powers of 2\n            qc.cx(0, i)\n    \n    # Step 3: Apply Z gate to introduce the phase\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 23, "result": "WA", "execution_time": "1388 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in a divide-and-conquer approach\n    current_layer = list(range(1, n))\n    \n    while len(current_layer) > 1:\n        next_layer = []\n        for i in range(0, len(current_layer), 2):\n            if i + 1 < len(current_layer):\n                qc.cx(current_layer[i], current_layer[i+1])\n                next_layer.append(current_layer[i+1])\n            else:\n                next_layer.append(current_layer[i])\n        current_layer = next_layer\n    \n    # Apply final CNOT gate from qubit 0 to the last qubit in the chain\n    qc.cx(0, current_layer[0])\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 24, "result": "WA", "execution_time": "1183 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in parallel layers to reduce depth\n    step = 1\n    while step < n:\n        for i in range(0, n - step, step * 2):\n            qc.cx(i, i + step)\n        step *= 2\n    \n    # Step 3: Apply a final CNOT gate to the last qubit\n    if step // 2 < n:\n        qc.cx(0, n - 1)\n\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 25, "result": "WA", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in layers to maximize parallelism\n    step = 2\n    while step < n:\n        for i in range(step, n, 2 * step):\n            qc.cx(0, i)\n        step *= 2\n    \n    # Step 3: Apply Z gate to introduce the phase\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 26, "result": "DLE", "execution_time": "1422 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in layers to maximize parallelism\n    step = 1\n    while step < n:\n        for i in range(step, n, 2 * step):\n            qc.cx(0, i)\n        step *= 2\n    \n    # Step 3: Apply Z gate to introduce the phase\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 27, "result": "WA", "execution_time": "1408 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in layers to maximize parallelism\n    step = 1\n    while step < n:\n        for i in range(step, n, 6 * step):\n            qc.cx(0, i)\n        step *= 2\n    \n    # Step 3: Apply Z gate to introduce the phase\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A4", "user": "AFE00F96D78C8", "submission_order": 28, "result": "DLE", "execution_time": "1386 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in layers to maximize parallelism\n    step = 1\n    while step < n:\n        for i in range(step, n, 2 * step):\n            qc.cx(0, i)\n        step *= 2\n    \n    # Step 3: Apply Z gate to introduce the phase\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A002AC2791D6C", "submission_order": 1, "result": "RE", "execution_time": "1628 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n//4):\n        qc.cx(0,i*4)\n    for i in range(n//4):\n        qc.cx(i*4,i*4+n//8)\n    for i in range(n//8):\n        qc.cx(2*i,2*i+1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A002AC2791D6C", "submission_order": 2, "result": "RE", "execution_time": "1091 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n//2,n,n//2):\n        qc.cx(0,i)\n    for i in range(0,n,n//2):\n        qc.cx(i,i+n//4)\n    for i in range(0,n,n//4):\n        qc.cx(i,i+n//8)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A002AC2791D6C", "submission_order": 3, "result": "RE", "execution_time": "1119 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(0,n,n//2):\n        if(n//2>0):\n            qc.cx(0,i+n//2)\n    for i in range(0,n,n//2):\n        if(n//4>0):\n            qc.cx(i,i+n//4)\n    for i in range(0,n,n//4):\n        if(n//8>0):\n            qc.cx(i,i+n//8)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A002AC2791D6C", "submission_order": 4, "result": "RE", "execution_time": "1552 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(0,n,n):\n        if(n//2>0):\n            qc.cx(i,i+n//2)\n    for i in range(0,n,n//2):\n        if (n//4>0):\n            qc.cx(i,i+n//4)\n    for i in range(0,n,n//4):\n        if (n//8>0):\n            qc.cx(i,i+n//8)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A002AC2791D6C", "submission_order": 5, "result": "RE", "execution_time": "1345 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(0,n,n):\n        if(n//2>0):\n            qc.cx(i,i+n//2)\n    for i in range(0,n,n//2):\n        if (n//4>0):\n            qc.cx(i,i+n//4)\n    for i in range(0,n,n//4):\n        if (n//8>0):\n            qc.cx(i,i+n//8)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A002AC2791D6C", "submission_order": 6, "result": "AC", "execution_time": "1902 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    cnt=0\n    for i in range(0,n):\n        for j in range(2**i):\n            if (j+2**i < n):\n                qc.cx(j,j+2**i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A01519F2C05A9", "submission_order": 1, "result": "AC", "execution_time": "1724 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qbit_list = list(range(1, n, 1))\n    done_list = [0]\n    is_done = False\n    while(True):\n\n        doing_list = []\n        for c in done_list:\n            if len(qbit_list)==0:\n                is_done = True\n                break\n            target = qbit_list.pop(0)\n            qc.cx(c, target)\n            doing_list.append(target)\n\n        if is_done:\n            break\n        done_list.extend(doing_list)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A04579D0D766B", "submission_order": 1, "result": "DLE", "execution_time": "1348 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(n//2-1)\n    qc.cx(n//2-1,n//2)\n    for i in range((n-2)//2+1):\n        if 0 <= n//2-2-i < n:\n            qc.cx(n//2-1,n//2-2-i)\n        if 0 <= n//2+i+1 < n:\n            qc.cx(n//2,n//2+i+1)\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A04579D0D766B", "submission_order": 2, "result": "WA", "execution_time": "1241 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(n//2-1)\n    qc.cx(n//2-1,n//2)\n    if n <= 6:\n        for i in range((n-2)//2+1):\n            if 0 <= n//2-2-i < n:\n                qc.cx(n//2-1,n//2-2-i)\n            if 0 <= n//2+i+1 < n:\n                qc.cx(n//2,n//2+i+1)\n    else:\n        pass\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A04579D0D766B", "submission_order": 3, "result": "RE", "execution_time": "1068 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(n//2-1)\n    qc.cx(n//2-1,n//2)\n    if n <= 8:\n        for i in range((n-2)//2+1):\n            if 0 <= n//2-2-i < n:\n                qc.cx(n//2-1,n//2-2-i)\n            if 0 <= n//2+i+1 < n:\n                qc.cx(n//2,n//2+i+1)\n    else:\n        pas\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A04579D0D766B", "submission_order": 4, "result": "WA", "execution_time": "1597 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(n//2-1)\n    qc.cx(n//2-1,n//2)\n    if n <= 8:\n        for i in range((n-2)//2+1):\n            if 0 <= n//2-2-i < n:\n                qc.cx(n//2-1,n//2-2-i)\n            if 0 <= n//2+i+1 < n:\n                qc.cx(n//2,n//2+i+1)\n    else:\n        pass\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A04579D0D766B", "submission_order": 5, "result": "WA", "execution_time": "1618 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(n//2-1)\n    qc.cx(n//2-1,n//2)\n    if n <= 10:\n        for i in range((n-2)//2+1):\n            if 0 <= n//2-2-i < n:\n                qc.cx(n//2-1,n//2-2-i)\n            if 0 <= n//2+i+1 < n:\n                qc.cx(n//2,n//2+i+1)\n    else:\n        pass\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A04579D0D766B", "submission_order": 6, "result": "WA", "execution_time": "1756 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(n//2-1)\n    qc.cx(n//2-1,n//2)\n    if n <= 9:\n        for i in range((n-2)//2+1):\n            if 0 <= n//2-2-i < n:\n                qc.cx(n//2-1,n//2-2-i)\n            if 0 <= n//2+i+1 < n:\n                qc.cx(n//2,n//2+i+1)\n    else:\n        pass\n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A04579D0D766B", "submission_order": 7, "result": "RE", "execution_time": "1437 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    if n < 10:\n        qc.h(n//2-1)\n        qc.cx(n//2-1,n//2)\n        for i in range((n-2)//2+1):\n            if 0 <= n//2-2-i < n:\n                qc.cx(n//2-1,n//2-2-i)\n            if 0 <= n//2+i+1 < n:\n                qc.cx(n//2,n//2+i+1)\n    else:\n        qc.h(0)\n\n        qc.cx(0,7)\n\n        qc.cx(0,3)\n        if n >= 11:\n            qc.cx(7,11)\n        \n        qc.cx(0,2)\n        qc.cx(3,5)\n        qc.cx(7,9)\n        if n >= 13:\n            qc.cx(11,13)\n\n        qc.cx(0,1)\n        qc.cx(3,4)\n        qc.cx(5,6)\n        qc.cx(7,8)\n        if n >= 10:\n            qc.cx(9,10)\n        if n >= 12:\n            qc.cx(11,12)\n        if n >= 14:\n            qc.cx(13,14)\n  \n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A04579D0D766B", "submission_order": 8, "result": "AC", "execution_time": "2182 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    if n < 10:\n        qc.h(n//2-1)\n        qc.cx(n//2-1,n//2)\n        for i in range((n-2)//2+1):\n            if 0 <= n//2-2-i < n:\n                qc.cx(n//2-1,n//2-2-i)\n            if 0 <= n//2+i+1 < n:\n                qc.cx(n//2,n//2+i+1)\n    else:\n        qc.h(0)\n\n        qc.cx(0,7)\n\n        qc.cx(0,3)\n        if n > 11:\n            qc.cx(7,11)\n        \n        qc.cx(0,2)\n        qc.cx(3,5)\n        qc.cx(7,9)\n        if n > 13:\n            qc.cx(11,13)\n\n        qc.cx(0,1)\n        qc.cx(3,4)\n        qc.cx(5,6)\n        qc.cx(7,8)\n        if n > 10:\n            qc.cx(9,10)\n        if n > 12:\n            qc.cx(11,12)\n        if n > 14:\n            qc.cx(13,14)\n  \n    qc.z(0)   \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A0ACCE45A7E36", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n        qc.h(0)\n    end = 1\n    while end < n:\n        for left in range(end):\n            qc.cx(left, end)\n            end += 1\n            if end == n:\n                break\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A0ACCE45A7E36", "submission_order": 2, "result": "WA", "execution_time": "1449 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    l = int(np.ceil(np.log2(n)))\n\n    for m in range(l, 0, -1):\n        step = 2 ** m\n        half_step = 2 ** (m - 1)\n    for k in range(0, n, step):\n        if k + half_step < n:\n            qc.cx(k, k + half_step)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A0ACCE45A7E36", "submission_order": 3, "result": "WA", "execution_time": "1185 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    l = int(np.ceil(np.log2(n)))\n\n    for m in range(l, 0, -1):\n        step = 2 ** m\n        half_step = 2 ** (m - 1)\n        for k in range(0, n, step):\n            if k + half_step < n:\n                qc.cx(k, k + half_step)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A0ACCE45A7E36", "submission_order": 4, "result": "AC", "execution_time": "2037 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    l = int(np.ceil(np.log2(n)))\n\n    for m in range(l, 0, -1):\n        step = 2 ** m\n        half_step = 2 ** (m - 1)\n        for k in range(0, n, step):\n            if k + half_step < n:\n                qc.cx(k, k + half_step)\n    \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A1929A17BCF09", "submission_order": 1, "result": "AC", "execution_time": "1722 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n\n    cur = 1\n    max = 1\n    while True:            \n        for i in reversed(range(max)):\n            qc.cx(i, cur)\n            print(f'{i}->{cur}')\n            cur += 1\n            if cur >= n:\n                qc.z(0)\n                return qc\n        max += 1\n'''"}
{"problem": "QPC002_A5", "user": "A197F4335A74B", "submission_order": 1, "result": "AC", "execution_time": "2686 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n\n    i = 1\n    while i < n:\n        for j in range(i):\n            if i + j < n:\n                qc.cx(j, i + j)\n        i *= 2\n    \n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A19B7D7B81F4E", "submission_order": 1, "result": "AC", "execution_time": "2151 ms", "memory": "161 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    def rec(l, r):\n        if r - l <= 1:\n            return\n        m = (l + r) // 2\n        qc.cx(l, m)\n        rec(l, m)\n        rec(m, r)\n    rec(0, n)\n    # for i in range(1, n):\n    #     qc.cx(0, i)\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     n = 15\n#     qc = solve(n)\n#     sv = Statevector(qc)\n#     print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_A5", "user": "A1A33597D7EA7", "submission_order": 1, "result": "WA", "execution_time": "2084 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    circuitEnd = False\n    for i in range(1, 5):\n        for j in range(i):\n            if (j + i >= n):\n                circuitEnd = True\n                break\n            qc.cx(j, j + i)\n        if (circuitEnd):\n            break\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A1A33597D7EA7", "submission_order": 2, "result": "AC", "execution_time": "2332 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    circuitEnd = False\n    for i in [int(pow(2, x)) for x in range(0, 4)]:\n\n        for j in range(i):\n            if (j + i >= n):\n                circuitEnd = True\n                break\n            qc.cx(j, j + i)\n        if (circuitEnd):\n            break\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A1EED261A60E7", "submission_order": 1, "result": "DLE", "execution_time": "1217 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i//2,i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A1EED261A60E7", "submission_order": 2, "result": "DLE", "execution_time": "1158 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    A=[None,0,0,0,0,0,1,1,1,1,2,2,2,3,3,3,4,4,5,6]\n    for i in range(1,n):\n        qc.cx(A[i],i)\n    qc.z(A[n])\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A1EED261A60E7", "submission_order": 3, "result": "DLE", "execution_time": "1339 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    A=[None,0,0,0,0,0,1,1,1,1,2,2,2,3,3,3,4,4,5,7]\n    for i in range(1,n):\n        qc.cx(A[i],i)\n    qc.z(A[n])\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A1EED261A60E7", "submission_order": 4, "result": "AC", "execution_time": "2580 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    A=[None,0,0,0,0,0,1,1,1,1,2,2,2,3,3,3,4,4,5,6]\n    for i in range(1,n):\n        qc.cx(A[i],i)\n    qc.z(A[n+1])\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A22824C351484", "submission_order": 1, "result": "AC", "execution_time": "2817 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef dnc(qc: QuantumCircuit, l: int, r: int) -> None:\n    if l == r:\n        return\n    m = (l + 1 + r) // 2\n    qc.cx(l, m)\n    dnc(qc, l, m - 1)\n    dnc(qc, m, r)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    qc.h(0)\n    qc.z(0)\n    dnc(qc, 0, n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A230C8FCB8D8B", "submission_order": 1, "result": "RE", "execution_time": "1565 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n-1)\n    def halve(qc, i, j):\n        if i != j: \n            half = (i + j) // 2\n            if i != half:\n                qc.cx(i, half)\n            if (half + 1) != j:\n                qc.cx(j, half + 1)\n            return qc, half\n        return qc, None\n    \n    qc, half = halve(qc, 0, n - 1)  \n\n    qc, half1 = halve(qc, 0, half)\n    qc, half2 = halve(qc, half + 1, n - 1)\n\n    qc, _ = halve(qc, 0, half1)\n    qc, _ = halve(qc,  half1 +1, half)\n\n    qc, _ = halve(qc, half + 1, half2)\n    qc, _ = halve(qc, half2 + 1, n - 1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A230C8FCB8D8B", "submission_order": 2, "result": "AC", "execution_time": "1952 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n-1)\n    def halve(qc, i, j):\n        if i != j: \n            half = (i + j) // 2\n            if i != half:\n                qc.cx(i, half)\n            if (half + 1) != j:\n                qc.cx(j, half + 1)\n            return qc, half\n        return qc, None\n    \n    qc, half = halve(qc, 0, n - 1)  \n\n    if half:\n        qc, half1 = halve(qc, 0, half)\n        qc, half2 = halve(qc, half + 1, n - 1)\n        if half1:\n            qc, _ = halve(qc, 0, half1)\n            qc, _ = halve(qc,  half1 +1, half)\n        if half2:\n            qc, _ = halve(qc, half + 1, half2)\n            qc, _ = halve(qc, half2 + 1, n - 1)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 1, "result": "WA", "execution_time": "2040 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(n - 1):\n        qc.cz(0, i + 1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 2, "result": "DLE", "execution_time": "1682 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 3, "result": "RE", "execution_time": "2250 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(1, n):\n        if i % 2 == 0:\n            qc.cx(0, i)\n        else:\n            qc.cx(1, i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 4, "result": "DLE", "execution_time": "2045 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(1, n):\n        if i % 2 == 1:\n            qc.cx(0, i)\n        else:\n            qc.cx(1, i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 5, "result": "DLE", "execution_time": "1620 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(1, n):\n        if i % 3 == 1:\n            qc.cx(0, i)\n        elif i % 3 == 2:\n            qc.cx(1, i)\n        else:\n            qc.cx(2, i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 6, "result": "DLE", "execution_time": "1604 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        if i % 3 == 1:\n            qc.cx(0, i)\n        elif i % 3 == 2:\n            qc.cx(1, i)\n        else:\n            qc.cx(2, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 7, "result": "DLE", "execution_time": "1662 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        if i % 3 != 0:\n            qc.cx(0, i)\n        else:\n            qc.cx(1, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 8, "result": "DLE", "execution_time": "1811 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        if i % 2 != 0:\n            qc.cx(0, i)\n        else:\n            qc.cx(1, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 9, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        if i % 4 == 1\n            qc.cx(0, i)\n        elif i % 4 == 2:\n            qc.cx(1, i)\n        elif i % 4 == 3:\n            qc.cx(2, i)\n        else :\n            qc.cx(3, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 10, "result": "DLE", "execution_time": "1900 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        if i % 4 == 1:\n            qc.cx(0, i)\n        elif i % 4 == 2:\n            qc.cx(1, i)\n        elif i % 4 == 3:\n            qc.cx(2, i)\n        else :\n            qc.cx(3, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 11, "result": "RE", "execution_time": "1651 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(0, math.log2(n)):\n        for j in range(0, pow(2, i)):\n            qc.cx(j, j + i + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 12, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(0, (int)math.log2(n)):\n        for j in range(0, pow(2, i)):\n            qc.cx(j, j + i + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 13, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(0, (i)math.log2(n)):\n        for j in range(0, pow(2, i)):\n            qc.cx(j, j + i + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 14, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(0, int(math.log2(n))):\n        for j in range(0, pow(2, i)):\n            qc.cx(j, j + i + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 15, "result": "WA", "execution_time": "1736 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(0, int(math.log2(n))):\n        for j in range(0, pow(2, i)):\n            qc.cx(j, j + i + 1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 16, "result": "RE", "execution_time": "1622 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2 ** i):\n            if (j + 2 ** i) > n:\n                break\n            qc.cx(j, j + 2 ** i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 17, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    cnt = 0\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2 ** i):\n            qc.cx(j, j + 2 ** i)\n            cnt++\n\n            if cnt == n:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 18, "result": "RE", "execution_time": "1615 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    cnt = 0\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2 ** i):\n            qc.cx(j, j + 2 ** i)\n            cnt+=1\n\n            if cnt == n:\n                break\n        if cnt == n:\n            break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 19, "result": "RE", "execution_time": "1690 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    cnt = 0\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if cnt == n:\n                break\n            qc.cx(j, j + 2**i)\n            cnt+=1\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A294C07C8E71C", "submission_order": 20, "result": "AC", "execution_time": "2099 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    cnt = 0\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if j + 2**i == n:\n                break\n            qc.cx(j, j + 2**i)\n            cnt+=1\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A2E25F599BCCA", "submission_order": 1, "result": "AC", "execution_time": "2262 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    st = list(range(n-1, 0, -1))\n    nn = 1\n    while st:\n        for i in range(nn):\n            j = st.pop()\n            qc.cx(i, j)\n            nn += 1\n            if len(st) == 0:\n                break\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A2E81A1613F50", "submission_order": 1, "result": "DLE", "execution_time": "1694 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply Z gate to the first qubit to introduce the phase\n    qc.z(0)\n    \n    # Step 3: Apply CNOT gates with qubit 0 as the control and the others as targets\n    # We apply CNOT gates in parallel where possible\n    if n > 1:\n        for i in range(1, n):\n            qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A2E81A1613F50", "submission_order": 2, "result": "WA", "execution_time": "1149 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in a modified manner\n    for i in range(1, n):\n        qc.cz(0, i)\n    \n    # Step 3: Apply a final CNOT gate between the first qubit and all others\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A2E81A1613F50", "submission_order": 3, "result": "DLE", "execution_time": "1224 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    qc.z(0)\n    \n    # Step 3: Apply a final CNOT gate between the first qubit and all others\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A2E81A1613F50", "submission_order": 4, "result": "WA", "execution_time": "1460 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates between the first qubit and each of the other qubits\n    if n > 1:\n        qc.cx(0, 1)  # Depth 2\n    if n > 2:\n        qc.ccx(0, 1, 2)  # Using Toffoli gate (multi-control XOR) - Depth 3\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A2E81A1613F50", "submission_order": 5, "result": "WA", "execution_time": "1474 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply a controlled Z (CZ) gate between all pairs of qubits\n    if n > 1:\n        qc.cz(0, 1)  # Depth 2\n    if n > 2:\n        qc.cz(1, 2)  # Depth 2 (since it can be in parallel with the first CZ)\n    if n > 3:\n        qc.cz(2, 3)  # Depth 3 (this is the final depth)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A2ED731EC7C1F", "submission_order": 1, "result": "AC", "execution_time": "1866 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    kouho = []\n    for i in range(n-1):\n        target = i + 1\n        if kouho:\n            a = kouho.pop()\n            qc.cx(a, target)\n        else:\n            qc.cx(0, target)\n            for j in range(1, target):\n                kouho.append(j)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3826F8E99454", "submission_order": 1, "result": "AC", "execution_time": "1806 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    now = 1\n    while now<=n-1:\n        for i in range(now):\n            if now+i+1>=n:\n                break\n            qc.cx(i+1,i+1+now)\n        now *= 2\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3B7264E87B75", "submission_order": 1, "result": "AC", "execution_time": "2146 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    used = [False]*n\n    used[0] = True\n    ones = [0]\n    while True:\n        if len(ones) == n:\n            break\n        nones = []\n        for i in ones:\n            nones.append(i)\n            for j in range(0,n):\n                if not used[j]:\n                    qc.cx(i,j)\n                    used[j] = True\n                    nones.append(j)\n                    break\n        ones = nones[:]\n    # Write your code here:\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3CC9DA78BC10", "submission_order": 1, "result": "RE", "execution_time": "1039 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n):\n        if i % 2 == 0:\n            if i != 0:\n                qc.x(i)\n            qc.cx(i, i + 1)\n    for i in range(n):\n        if i % 2 == 1:\n            if i != n - 1:\n                qc.x(i)\n                qc.cx(i, i + 1)\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3CC9DA78BC10", "submission_order": 2, "result": "WA", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(n):\n        if i % 2 == 0:\n            if i != 0:\n                qc.x(i)\n            if i != n - 1:\n                qc.cx(i, i + 1)\n    for i in range(n):\n        if i % 2 == 1:\n            if i != n - 1:\n                qc.x(i)\n                qc.cx(i, i + 1)\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3CC9DA78BC10", "submission_order": 3, "result": "AC", "execution_time": "1932 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    max_qubit = 1\n    for i in range(4):\n        for j in range(2 ** i):\n            qc.cx(j, j + 2 ** i)\n            max_qubit = max(j + 2 ** i, max_qubit)\n            if max_qubit == n - 1:\n                break\n        if max_qubit == n - 1:\n            break\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3D60120F805D", "submission_order": 1, "result": "AC", "execution_time": "1685 ms", "memory": "157 MiB", "code": "'''python\nimport math\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import (\n    C3XGate,\n    C3SXGate,\n    C4XGate,\n    CCXGate,\n    DCXGate,\n    CHGate,\n    CPhaseGate,\n    CRXGate,\n    CRYGate,\n    CRZGate,\n    CSwapGate,\n    CSXGate,\n    CUGate,\n    CU1Gate,\n    CU3Gate,\n    CXGate,\n    CYGate,\n    CZGate,\n    CCZGate,\n    HGate,\n    IGate,\n    MCPhaseGate,\n    PhaseGate,\n    RCCXGate,\n    RC3XGate,\n    RXGate,\n    RXXGate,\n    RYGate,\n    RYYGate,\n    RZGate,\n    RZZGate,\n    RZXGate,\n    XXMinusYYGate,\n    XXPlusYYGate,\n    ECRGate,\n    SGate,\n    SdgGate,\n    CSGate,\n    CSdgGate,\n    SwapGate,\n    iSwapGate,\n    SXGate,\n    SXdgGate,\n    TGate,\n    TdgGate,\n    UGate,\n    U1Gate,\n    U2Gate,\n    U3Gate,\n    XGate,\n    YGate,\n    ZGate,\n)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for b in [8, 4, 2, 1]:\n        for j in range(b, n, b * 2):\n            i = j - b\n            qc.cx(i, j)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3DC9BC9AB84B", "submission_order": 1, "result": "AC", "execution_time": "1945 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    if (n == 3):\n        qc.cx(0,2)\n    elif (n==4):\n        qc.cx(0,2)\n        qc.cx(1,3)\n    elif (n==5):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n    elif (n==6):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n    elif (n==7):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n    elif (n==8):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n    elif (n==9):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n    elif (n==10):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n    elif (n==11):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n    elif (n==12):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n    elif (n==13):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n    elif (n==14):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n        qc.cx(5,13)\n    elif (n==15):\n        qc.cx(0,2)\n        qc.cx(1,3)\n        qc.cx(0,4)\n        qc.cx(1,5)\n        qc.cx(2,6)\n        qc.cx(3,7)\n        qc.cx(0,8)    \n        qc.cx(1,9)    \n        qc.cx(2,10)\n        qc.cx(3,11)\n        qc.cx(4,12)\n        qc.cx(5,13)\n        qc.cx(6,14)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3E64874F3980", "submission_order": 1, "result": "AC", "execution_time": "2083 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\na = [[0, 1], [0, 2], [1, 3], [0, 4], [1, 5], [2, 6], [3, 7], [0, 8], [1, 9], [2, 10], [3, 11], [4, 12], [5, 13], [6, 14]]\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n-1):\n        qc.cx(a[i][0],a[i][1])\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3EEC60127B9B", "submission_order": 1, "result": "RE", "execution_time": "1708 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    if n <= 3:\n        qc.z(0)\n        for i in range(1, n):\n            qc.cx(0, i)\n    elif n <= 6:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(1, 4)\n        qc.cx(2, 5)\n        qc.z(0)\n    else:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(1, 4)\n        qc.cx(2, 5)\n        qc.z(0)\n        count = 0\n        while count+6 < n:\n            qc.cx(count, count+6)\n            count += 1\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A3EEC60127B9B", "submission_order": 2, "result": "AC", "execution_time": "1742 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    if n <= 3:\n        qc.z(0)\n        for i in range(1, n):\n            qc.cx(0, i)\n    elif n <= 6:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        count = 0\n        while count+3 < n:\n            qc.cx(count, count+3)\n            count += 1\n        qc.z(0)\n    else:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(1, 4)\n        qc.cx(2, 5)\n        qc.z(0)\n        count = 0\n        while count+6 < n:\n            qc.cx(count, count+6)\n            count += 1\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4080138B34EA", "submission_order": 1, "result": "DLE", "execution_time": "2227 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    if n == 3:\n        return solve3()\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    ans = [0 for _ in range(n)]\n    qc.cx(0, n//2)\n    ans[0] = 1\n    ans[n//2] = 1\n    r = (n//2)//2\n    while not all(ans):\n        for i in range(n-r):\n            if ans[i] == 1 and ans[i+r] == 0:\n                qc.cx(i, i+r)\n                ans[i+r] = 1\n        if r != 1:\n            r //= 2\n        else:\n            break\n    qc.z(0)\n    return qc\n\ndef solve3():\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, 3):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4080138B34EA", "submission_order": 2, "result": "AC", "execution_time": "2247 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    if n == 3:\n        return solve3()\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    ans = [0 for _ in range(n)]\n    qc.cx(0, n//2)\n    ans[0] = 1\n    ans[n//2] = 1\n    r = (n//2)\n    while not all(ans):\n        for i in range(n-r):\n            if ans[i] == 1 and ans[i+r] == 0:\n                qc.cx(i, i+r)\n                ans[i+r] = 1\n        r //= 2\n    qc.z(0)\n    return qc\n\ndef solve3():\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, 3):\n        qc.cx(0, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A431B57D0496D", "submission_order": 1, "result": "RE", "execution_time": "1101 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    step = 2**ceil(log2(n))\n    while step:\n        for i in range(0, n, 2 * step):\n            if i + step < n:\n                qc.cx(i, i + step)\n        step //= 2\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A431B57D0496D", "submission_order": 2, "result": "AC", "execution_time": "2077 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ceil,log2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    step = 2**ceil(log2(n))\n    while step:\n        for i in range(0, n, 2 * step):\n            if i + step < n:\n                qc.cx(i, i + step)\n        step //= 2\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A433D21B5349C", "submission_order": 1, "result": "AC", "execution_time": "2965 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    idx1 = 0\n    next1 = 1\n    breakF = False\n    while not breakF:\n        for i, j in enumerate(range(idx1 + 1, idx1 + next1 + 1)):\n            if j >= n:\n                breakF = True\n                break\n            qc.cx(i, j)\n        if breakF:\n            break\n        idx1 += next1\n        next1 *= 2\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A436A8BBD72E2", "submission_order": 1, "result": "WA", "execution_time": "1536 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard to the first qubit\n    qc.h(0)\n    \n    # Entangle all other qubits with the first one\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Apply X gates to all qubits\n    for i in range(n):\n        qc.x(i)\n    \n    # Apply Hadamard gates to all qubits except the first one\n    for i in range(1, n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A436A8BBD72E2", "submission_order": 2, "result": "WA", "execution_time": "1285 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n\n    # Apply CNOT gates to create the desired superposition\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A436A8BBD72E2", "submission_order": 3, "result": "WA", "execution_time": "1155 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n\n    # Apply CNOT gates to create the desired entanglement\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A436A8BBD72E2", "submission_order": 4, "result": "WA", "execution_time": "1498 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\n  # Apply Hadamard gates to all qubits\n  for i in range(n):\n    qc.h(i)\n\n  # Apply CNOT gates for efficient entanglement (reduce depth)\n  for i in range(1, n):\n    for j in range(i):\n      qc.cx(j, i)  # Apply CNOT from lower qubits to higher qubits\n\n  return qc\n'''"}
{"problem": "QPC002_A5", "user": "A45D0458FF08A", "submission_order": 1, "result": "AC", "execution_time": "2008 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    a=1\n    while a<n:\n        for i in range(a):\n            if i+a<n:\n                qc.cx(i,i+a)\n        a*=2\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A496D8B504B48", "submission_order": 1, "result": "AC", "execution_time": "2187 ms", "memory": "143 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-math.pi, 0)\n\n    log = int(math.log2(n - 1)) + 1\n\n    swapped = set([0])\n\n    for i in range(log - 1, -1, -1):\n        done = set()\n        for j in range(n):\n            if j not in swapped:\n                continue\n\n            next_j = j + 2**i\n            print(j, next_j)\n            if next_j < n and next_j not in swapped:\n                done.add(next_j)\n                qc.cx(j, next_j)\n        swapped |= done\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4B7AB71173A3", "submission_order": 1, "result": "WA", "execution_time": "1272 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        mbit = 0\n        for j in range(5): \n            if i>>j&1: mbit = j\n        qc.cx(i, i-(1<<mbit))\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4B7AB71173A3", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        mbit = 0\n        for j in range(5): \n            if i>>j&1: mbit = j\n        qc.cx(i, 1<<mbit)\n    qc.z(n-)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4B7AB71173A3", "submission_order": 3, "result": "RE", "execution_time": "1327 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        mbit = 0\n        for j in range(5): \n            if i>>j&1: mbit = j\n        qc.cx(i, i-1<<mbit)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4B7AB71173A3", "submission_order": 4, "result": "AC", "execution_time": "1736 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1, n):\n        mbit = 0\n        for j in range(5): \n            if i>>j&1: mbit = j\n        qc.cx(i-(1<<mbit), i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4ED07C9B52E7", "submission_order": 1, "result": "AC", "execution_time": "2202 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    # log depth\n    import math\n\n    l = int(math.ceil(math.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2**m):\n            if k + 2 ** (m - 1) >= n:\n                continue\n            qc.cx(k, k + 2 ** (m - 1))\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 1, "result": "DLE", "execution_time": "1910 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=0\n    if n>2:\n        for i in range(n-2):\n            if c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            else:\n                qc.cx(1,i+2)\n                c=c+1\n\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 2, "result": "DLE", "execution_time": "2040 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=2\n    if n>2:\n        for i in range(n-2):\n            if c%4==0:\n                qc.cx(2,i+2)\n                c=c+1\n            elif c%3==0:\n                qc.cx(1,i+2)\n                c=c+1\n            elif c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            else:\n                qc.cx(3,i+2)\n                c=c+1\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 3, "result": "DLE", "execution_time": "2078 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=2\n    if n>2:\n        for i in range(n-2):\n            if c%4==0:\n                qc.cx(2,i+2)\n                c=c+1\n            elif c%3==0:\n                qc.cx(1,i+2)\n                c=c+1\n            elif c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            elif c%5==0:\n                qc.cx(3,i+2)\n                c=c+1\n            else:\n                qc.cx(4,i+2)\n                c=c+1\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    gate = np.array([1,0,0,0],[0,1,0,0],[0,0,0,1],[0,0,-1,0])\n    ug = UnitaryGate(gate, label = \"ug\")\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.gate(0,1)\n    c=2\n    if n>2:\n        for i in range(n-2):\n            if c%4==0:\n                qc.cx(2,i+2)\n                c=c+1\n            elif c%3==0:\n                qc.cx(1,i+2)\n                c=c+1\n            elif c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            elif c%5==0:\n                qc.cx(3,i+2)\n                c=c+1\n            else:\n                qc.cx(4,i+2)\n                c=c+1\n    qc.barrier()\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=2\n    if n>2:\n        for i in range(n-2):\n            if c%4==0:\n                qc.cx(2,i+2)\n                c=c+1\n            elif c%3==0:\n                qc.cx(1,i+2)\n                c=c+1\n            elif c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            elif c%5==0:\n                qc.cx(3,i+2)\n                c=c+1\n            else:\n                qc.cx(4,i+2)\n                c=c+1\n    qc.barrier()\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=2\n    if n>2:\n        for i in range(n-2):\n            if c%4==0:\n                qc.cx(2,i+2)\n                c=c+1\n            elif c%3==0:\n                qc.cx(1,i+2)\n                c=c+1\n            elif c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            elif c%5==0:\n                qc.cx(3,i+2)\n                c=c+1\n            else:\n                qc.cx(4,i+2)\n                c=c+1\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 7, "result": "DLE", "execution_time": "1763 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=2\n    if n>2:\n        for i in range(n-2):\n            if c%4==0:\n                qc.cx(2,i+2)\n                c=c+1\n            elif c%3==0:\n                qc.cx(1,i+2)\n                c=c+1\n            elif c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            elif c%5==0:\n                qc.cx(3,i+2)\n                c=c+1\n            else:\n                qc.cx(4,i+2)\n                c=c+1\n    qc.barrier()\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 8, "result": "DLE", "execution_time": "2085 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=2\n    if n>2:\n        for i in range(n-2):\n            if c%4==0:\n                qc.cx(2,i+2)\n                c=c+1\n            elif c%3==0:\n                qc.cx(1,i+2)\n                c=c+1\n            elif c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            elif c%5==0:\n                qc.cx(3,i+2)\n                c=c+1\n            else:\n                qc.cx(4,i+2)\n                c=c+1\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F592A06E228", "submission_order": 9, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    c=2\n    if n>2:\n        for i in range(n-2):\n            if c%4==0:\n                qc.cx(2,i+2)\n                c=c+1\n            elif c%3==0:\n                qc.cx(1,i+2)\n                c=c+1\n            elif c%2==0:\n                qc.cx(0,i+2)\n                c=c+1\n            elif c%5==0:\n                qc.cx(3,i+2)\n                c=c+1\n            else:\n                qc.cx(4,i+2)\n                c=c+1\n    if n==14\n        qc.z(3)\n    else\n        qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A4F71F098D984", "submission_order": 1, "result": "AC", "execution_time": "2164 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for b in reversed(range(5)):\n        i = 0\n        while True:\n            if i + (1<<b) >= n:\n                break\n            qc.cx(i, i + (1<<b))\n            i += (1<<(b+1))\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5094193E3760", "submission_order": 1, "result": "AC", "execution_time": "2437 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2 ** i):\n            if 2 ** i + j == n:\n                break;\n            qc.cx(j, 2 ** i + j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A51775EB09620", "submission_order": 1, "result": "DLE", "execution_time": "1096 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.cx(0, i)\n\n    qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A51775EB09620", "submission_order": 2, "result": "AC", "execution_time": "1980 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j, 2**i + j)\n    qc.z(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A51A4ECAB5A6B", "submission_order": 1, "result": "AC", "execution_time": "2014 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0) \n    qc.h(0)\n    l = int(np.ceil(np.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5259979D3422", "submission_order": 1, "result": "AC", "execution_time": "2130 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    qc.h(0)\n\n    def f(x, y):\n        if y < n:\n            qc.cx(x, y)\n\n    f(0, 1)\n\n    f(0, 2)\n    f(1, 3)\n\n    f(0, 4)\n    f(1, 5)\n    f(2, 6)\n    f(3, 7)\n\n    f(0, 8)\n    f(1, 9)\n    f(2, 10)\n    f(3, 11)\n    f(4, 12)\n    f(5, 13)\n    f(6, 14)\n    f(7, 15)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5295D4420A6F", "submission_order": 1, "result": "AC", "execution_time": "1740 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    qc.cx(0,1)\n    if n>2:\n        ent_num=1\n        ent_num_tmp=1\n        while(True):\n            for i in range(ent_num+1):\n                qc.cx(i, ent_num+1+i)\n                ent_num_tmp+=1\n\n                if ent_num+i+1==n-1:\n                    break\n            else:\n                ent_num=ent_num_tmp\n                continue\n            break\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A54034382C113", "submission_order": 1, "result": "DLE", "execution_time": "1787 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(i // 2, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A54034382C113", "submission_order": 2, "result": "DLE", "execution_time": "1883 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(i // 4, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A54034382C113", "submission_order": 3, "result": "DLE", "execution_time": "1560 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(i // 3, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A54034382C113", "submission_order": 4, "result": "DLE", "execution_time": "1491 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(2, n + 1):\n        qc.cx(i // 2 - 1, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A54034382C113", "submission_order": 5, "result": "DLE", "execution_time": "1614 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(i // 2, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A54034382C113", "submission_order": 6, "result": "DLE", "execution_time": "1179 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i // 2 , i)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A54034382C113", "submission_order": 7, "result": "DLE", "execution_time": "1509 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i // 2 , i)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A54034382C113", "submission_order": 8, "result": "DLE", "execution_time": "1043 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i // 2 , i)\n    qc.z(n - 2)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A554CF6A0FF3C", "submission_order": 1, "result": "AC", "execution_time": "2960 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    l = int(np.ceil(np.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A586E780B36C9", "submission_order": 1, "result": "AC", "execution_time": "2061 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    qc.z(0)\n    m = 1\n    while m < n:\n        for i in range(m):\n            if i + m < n:\n                qc.cx(i, i + m)\n        m *= 2\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5AA8AF9531A8", "submission_order": 1, "result": "AC", "execution_time": "2150 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(0)\n\n    x=[1]\n    for i in range(1,n):\n        # print(x)\n        y=min(x)\n        for j in range(len(x)):\n            if y==x[j]:\n                break\n        qc.cx(j,i)\n        x[j]+=1\n        x+=x[j],\n        \n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5B450C5797B5", "submission_order": 1, "result": "AC", "execution_time": "2256 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    qc.cx(0, 1)\n\n    if n > 2:\n        qc.cx(0, 2)\n    if n > 3:\n        qc.cx(1, 3)\n\n    if n > 4:\n        qc.cx(0, 4)\n    if n > 5:\n        qc.cx(1, 5)\n    if n > 6:\n        qc.cx(2, 6)\n    if n > 7:\n        qc.cx(3, 7)\n\n    if n > 8:\n        qc.cx(0, 8)\n    if n > 9:\n        qc.cx(1, 9)\n    if n > 10:\n        qc.cx(2, 10)\n    if n > 11:\n        qc.cx(3, 11)\n    if n > 12:\n        qc.cx(4, 12)\n    if n > 13:\n        qc.cx(5, 13)\n    if n > 14:\n        qc.cx(6, 14)\n\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5BDEFD25DE6A", "submission_order": 1, "result": "WA", "execution_time": "1165 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    qc.h(0)\n\n    i = 0\n    while 2**i < n:\n        j = 2**i\n        for l in range(j):\n            \n            if j+l == n-1:\n                break\n            qc.cx(l,j+l)\n\n            \n        i = i+1\n    \n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5BDEFD25DE6A", "submission_order": 2, "result": "WA", "execution_time": "1451 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    # finding the mid qubit\n    i = 0\n    while 2**i < n:\n        j = 2**i\n        for l in range(j):\n            \n            if j+l == n-1:\n                break\n            qc.cx(l,j+l)\n\n            \n        i = i+1\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5BDEFD25DE6A", "submission_order": 3, "result": "WA", "execution_time": "1119 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    # finding the mid qubit\n    i = 0\n    while 2**i < n:\n        j = 2**i\n        for l in range(j):\n            \n            if j+l == n-1:\n                break\n            qc.cx(l,j+l)\n\n            \n        i = i+1\n\n    qc.barrier()\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5BDEFD25DE6A", "submission_order": 4, "result": "WA", "execution_time": "1142 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    # finding the mid qubit\n    i = 0\n    while 2**i < n:\n        j = 2**i\n        for l in range(j):\n            \n            if j+l == n-1:\n                break\n            qc.cx(l,j+l)\n\n            \n        i = i+1\n\n    #qc.barrier()\n    #qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5BDEFD25DE6A", "submission_order": 5, "result": "WA", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    # finding the mid qubit\n    i = 0\n    while 2**i < n:\n        j = 2**i\n        for l in range(j):\n            \n            if j+l == n-1:\n                break\n            qc.cx(l,j+l)\n\n            \n        i = i+1\n\n    #qc.barrier()\n    #qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5BDEFD25DE6A", "submission_order": 6, "result": "WA", "execution_time": "1140 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(0)\n    # finding the mid qubit\n    i = 0\n    while 2**i < n:\n        j = 2**i\n        for l in range(j):\n            \n            if j+l == n-1:\n                break\n            qc.cx(l,j+l)\n\n            \n        i = i+1\n\n    #qc.barrier()\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5BDEFD25DE6A", "submission_order": 7, "result": "AC", "execution_time": "2055 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(0)\n \n    l = int(np.ceil(np.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n    \n\n\n    \n\n    #qc.barrier()\n    qc.z(0)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5C364721EB68", "submission_order": 1, "result": "AC", "execution_time": "2057 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n == 2:\n        qc.cx(0, 1)\n    elif n == 3:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n    elif n== 4:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n    elif n == 5:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n    elif n == 6:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n    elif n == 7:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)\n    elif n == 8:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n    elif n == 9:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n    elif n == 10:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)\n    elif n == 11:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)\n    elif n == 12:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)        \n        qc.cx(4, 11)\n    elif n == 13:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)        \n        qc.cx(4, 11)        \n        qc.cx(3, 12)\n    elif n == 14:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)        \n        qc.cx(4, 11)        \n        qc.cx(3, 12)        \n        qc.cx(2, 13)\n    elif n == 15:\n        qc.cx(0, 1)\n        qc.cx(1, 2)\n        qc.cx(0, 3)\n        qc.cx(3, 4)\n        qc.cx(2, 5)\n        qc.cx(1, 6)        \n        qc.cx(0, 7)\n        qc.cx(7, 8)\n        qc.cx(6, 9)    \n        qc.cx(5, 10)        \n        qc.cx(4, 11)        \n        qc.cx(3, 12)        \n        qc.cx(2, 13)\n        qc.cx(1, 14)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5E698C5EE7FA", "submission_order": 1, "result": "RE", "execution_time": "2181 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-4):\n        if i % 3 == 0:\n            qc.cx(0, i+1)\n        elif i % 3 == 1:\n            qc.cx(1, i+1)\n        elif i % 3 == 2:\n            qc.cx(2, i+1)\n\n    qc.cx(3, n-3)\n    qc.cx(4, n-2)\n    qc.cx(5, n-1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5E698C5EE7FA", "submission_order": 2, "result": "DLE", "execution_time": "1954 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(n-1):\n        if i % 15 == 0:\n            qc.cx(0, i+1)\n        elif i % 15 == 1:\n            qc.cx(1, i+1)\n        elif i % 15 == 2:\n            qc.cx(2, i+1)\n        elif i % 15 == 3:\n            qc.cx(3, i+1)\n        elif i % 15 == 4:\n            qc.cx(4, i+1)\n        elif i % 15 == 5:\n            qc.cx(5, i+1)\n        elif i % 15 == 6:\n            qc.cx(6, i+1)\n        elif i % 15 == 7:\n            qc.cx(7, i+1)\n        elif i % 15 == 8:\n            qc.cx(8, i+1)\n        elif i % 15 == 9:\n            qc.cx(9, i+1)\n        elif i % 15 == 10:\n            qc.cx(10, i+1)\n        elif i % 15 == 11:\n            qc.cx(11, i+1)\n        elif i % 15 == 12:\n            qc.cx(12, i+1)\n        elif i % 15 == 13:\n            qc.cx(13, i+1)\n        elif i % 15 == 14:\n            qc.cx(14, i+1)\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5E698C5EE7FA", "submission_order": 3, "result": "DLE", "execution_time": "1900 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(n-2):\n        if i % 14 == 0:\n            qc.cx(0, i+2)\n        elif i % 14 == 1:\n            qc.cx(1, i+2)\n        elif i % 14 == 2:\n            qc.cx(2, i+2)\n        elif i % 14 == 3:\n            qc.cx(3, i+2)\n        elif i % 14 == 4:\n            qc.cx(4, i+2)\n        elif i % 14 == 5:\n            qc.cx(5, i+2)\n        elif i % 14 == 6:\n            qc.cx(6, i+2)\n        elif i % 14 == 7:\n            qc.cx(7, i+2)\n        elif i % 14 == 8:\n            qc.cx(8, i+2)\n        elif i % 14 == 9:\n            qc.cx(9, i+2)\n        elif i % 14 == 10:\n            qc.cx(10, i+2)\n        elif i % 14 == 11:\n            qc.cx(11, i+2)\n        elif i % 14 == 12:\n            qc.cx(12, i+2)\n        elif i % 14 == 13:\n            qc.cx(13, i+2)\n\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A5E698C5EE7FA", "submission_order": 4, "result": "AC", "execution_time": "2344 ms", "memory": "160 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.h(0)\n \n    for i in range(int(math.log2(n)) + 1):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j, 2**i + j)\n \n    qc.z(0)\n \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A618CBC1A08D3", "submission_order": 1, "result": "DLE", "execution_time": "1216 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    def entangle(idx1, idx2):\n        if idx2 > n - 1:\n            return\n        qc.cx(idx1, idx2)\n        entangle(idx2, (idx2 + 1) * 2 - 1)\n        entangle(idx2, (idx2 + 1) * 2)\n    entangle(0, 1)\n    entangle(0, 2)\n    qc.z(n- 1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A618CBC1A08D3", "submission_order": 2, "result": "RE", "execution_time": "1376 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    \n    for giver in range(math.ceil(math.log2(n))):\n        for taker in range(2 ** i):\n            if 2**giver + taker == n:\n                break\n            qc.cx(taker, 2**giver + taker)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A618CBC1A08D3", "submission_order": 3, "result": "RE", "execution_time": "1138 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    \n\n    for giver in range(math.ceil(math.log2(n))):\n        for taker in range(2 ** i):\n            if 2**giver + taker == n:\n                break\n            qc.cx(taker, 2**giver + taker)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A618CBC1A08D3", "submission_order": 4, "result": "AC", "execution_time": "2059 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n\n    for giver in range(math.ceil(math.log2(n))):\n        for taker in range(2 ** giver):\n            if 2**giver + taker == n:\n                break\n            qc.cx(taker, 2**giver + taker)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A66572FBE768B", "submission_order": 1, "result": "RE", "execution_time": "1322 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2 ** i):\n            if 2 ** i + j == n:\n                break\n            qc.cx(j, 2 ** i + j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A66572FBE768B", "submission_order": 2, "result": "AC", "execution_time": "1932 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2 ** i):\n            if 2 ** i + j == n:\n                break\n            qc.cx(j, 2 ** i + j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A66B20C778281", "submission_order": 1, "result": "RE", "execution_time": "1119 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_min_depth(depth):\n    min_val = min(depth.values())\n    for (k, v) in depth.items():\n        if v == min_val:\n            return k\n\ndef get_unentangled_qubit(e, n):\n    for i in range(n):\n        if i not in e:\n            return i\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    entangled_qubits = [0, 1]\n    depth = dict()\n    for i in range(n):\n        depth[i] = 0\n\n    depth[0] = 2\n    depth[1] = 2\n\n    while len(entangled_qubits) != n:\n\n        c = get_min_depth(depth)\n        t = get_unentangled_qubit(entangled_qubits, n)\n\n        qc.cx(c, t)\n        depth[c] = depth[c] + 1 \n        depth[t] = depth[c]\n        entangled_qubits.append(t)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A66B20C778281", "submission_order": 2, "result": "WA", "execution_time": "1271 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_min_depth(depth):\n    min_val = min(depth.values())\n    for (k, v) in depth.items():\n        if v == min_val:\n            return k\n\ndef get_unentangled_qubit(e, n):\n    for i in range(n):\n        if i not in e:\n            return i\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    entangled_qubits = [0, 1]\n    depth = dict()\n\n    depth[0] = 2\n    depth[1] = 2\n\n    while len(entangled_qubits) != n:\n\n        c = get_min_depth(depth)\n        t = get_unentangled_qubit(entangled_qubits, n)\n\n        qc.cx(c, t)\n        depth[c] = depth[c] + 1 \n        depth[t] = depth[c]\n        entangled_qubits.append(t)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A66B20C778281", "submission_order": 3, "result": "AC", "execution_time": "2176 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef get_min_depth(depth):\n    min_val = min(depth.values())\n    for (k, v) in depth.items():\n        if v == min_val:\n            return k\n\ndef get_unentangled_qubit(e, n):\n    for i in range(n):\n        if i not in e:\n            return i\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    entangled_qubits = [0, 1]\n    depth = dict()\n\n    depth[0] = 2\n    depth[1] = 2\n\n    while len(entangled_qubits) != n:\n\n        c = get_min_depth(depth)\n        t = get_unentangled_qubit(entangled_qubits, n)\n\n        qc.cx(c, t)\n        depth[c] = depth[c] + 1 \n        depth[t] = depth[c]\n        entangled_qubits.append(t)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A66FDC460C8BE", "submission_order": 1, "result": "AC", "execution_time": "1959 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef get_ghz_circuit(n_bits: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n_bits)\n    qc.h(0)\n    m = 0\n    while 1 << m < n_bits: m += 1\n    for k in range(m):\n        d = 1 << k\n        for i in range(d):\n            if i + d < n_bits: qc.cx(i, i + d)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = get_ghz_circuit(n)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A690533D4A87E", "submission_order": 1, "result": "DLE", "execution_time": "1654 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    for i in range(1, n, 4):\n        qc.cx(0, i)\n        if i+1 < n:\n            qc.cx(i, i+1)\n        if i+2 < n:\n            qc.cx(i, i+2)\n        if i+3 < n:\n            qc.cx(i, i+3)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A690533D4A87E", "submission_order": 2, "result": "DLE", "execution_time": "1675 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    for i in range(1, n, 5):\n        qc.cx(0, i)\n        if i+1 < n:\n            qc.cx(i, i+1)\n        if i+2 < n:\n            qc.cx(i, i+2)\n        if i+3 < n:\n            qc.cx(i, i+3)\n        if i+4 < n:\n            qc.cx(i, i+4)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A690533D4A87E", "submission_order": 3, "result": "DLE", "execution_time": "1601 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    l = 5\n    i = 1\n    while i < n:\n        qc.cx(0, i)\n        for j in range(1, l):\n            if i+j < n:\n                qc.cx(i, i+j)\n        i += l\n        j -= 1\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A690533D4A87E", "submission_order": 4, "result": "DLE", "execution_time": "1738 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    l = 6\n    i = 1\n    while i < n:\n        qc.cx(0, i)\n        for j in range(1, l):\n            if i+j < n:\n                qc.cx(i, i+j)\n        i += l\n        j -= 1\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A690533D4A87E", "submission_order": 5, "result": "DLE", "execution_time": "1820 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    l = 4\n    i = 1\n    while i < n:\n        qc.cx(0, i)\n        for j in range(1, l):\n            if i+j < n:\n                qc.cx(i, i+j)\n        i += l\n        j -= 1\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A690533D4A87E", "submission_order": 6, "result": "DLE", "execution_time": "1820 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    l = 5\n    i = 1\n    while i < n:\n        qc.cx(0, i)\n        for j in range(1, l):\n            if i+j < n:\n                qc.cx(i, i+j)\n        i += l\n        j = max(j-1, 1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A690533D4A87E", "submission_order": 7, "result": "DLE", "execution_time": "2111 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    \n    for i in range(n):\n        if 2 * i + 1 < n:\n            qc.cx(i, 2 * i + 1)\n        if 2 * i + 2 < n:\n            qc.cx(i, 2 * i + 2)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A690533D4A87E", "submission_order": 8, "result": "AC", "execution_time": "2279 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(0)\n    \n    depth = [0] * n\n    visited = [0] * n\n    visited[0] = 1\n    \n    for i in range(1, n):\n        m = n\n        p = 0\n        for j in range(i):\n            if depth[j] < m:\n                m = depth[j]\n                p = j\n        depth[p] += 1\n        depth[i] = depth[p]\n\n        qc.cx(p, i)\n\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6B3F6D0BEE58", "submission_order": 1, "result": "AC", "execution_time": "1740 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tgt = 1\n    for p in range(math.ceil(math.log2(n))):\n        for i in range(2**p):\n            if tgt < n:\n                qc.cx(i,tgt)\n                tgt += 1\n            else:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6BB33E223E4D", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ceil, log, \n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(log2(n)+1):\n        for j in range(2**i):\n            if 2**i + j = n:\n                break\n            qc.cx(j,2**i+j)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6BB33E223E4D", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ceil, log, \n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(int(log2(n)+1)):\n        for j in range(2**i):\n            if 2**i + j = n:\n                break\n            qc.cx(j,2**i+j)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6BB33E223E4D", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import ceil, log, \n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(int(log2(n))+1):\n        for j in range(2**i):\n            if 2**i + j = n:\n                break\n            qc.cx(j,2**i+j)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6BB33E223E4D", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import *\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(int(log2(n))+1):\n        for j in range(2**i):\n            if 2**i + j = n:\n                break\n            qc.cx(j,2**i+j)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6BB33E223E4D", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import *\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(int(log2(n))+1):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j,2**i+j)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6BB33E223E4D", "submission_order": 6, "result": "AC", "execution_time": "1764 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(int(math.log2(n))+1):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j,2**i+j)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6CB00C2F1DBA", "submission_order": 1, "result": "DLE", "execution_time": "1934 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to entangle the first qubit with the others\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply a phase shift to the last qubit to create the negative sign\n    qc.z(n-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A6F989CD66F29", "submission_order": 1, "result": "AC", "execution_time": "2214 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    i = 0\n    while 2**i < n:\n        for j in range(2**i):\n            if j+2**i < n:\n                qc.cx(j, j+2**i)\n        i += 1\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A740B48962C1D", "submission_order": 1, "result": "AC", "execution_time": "2049 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    count = 1\n    while count < n:\n        add = 0\n        for i in range(count):\n            if n - 1 < count + i:\n                break\n            qc.cx(i, count + i)\n            add += 1\n        count += add\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A74D572634CD5", "submission_order": 1, "result": "AC", "execution_time": "2069 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n):\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1,n):\n        q =  1 << i.bit_length() -1\n        r = i - q\n        print(i,q,r)\n        qc.cx(r,i)\n    \n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A780BB8BBA9F1", "submission_order": 1, "result": "WA", "execution_time": "1372 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(int(math.log2(n-1))):\n        for j in range(2**i):\n            if (j+2**i) > (n-1): continue\n            qc.cx(j,j+2**i)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A780BB8BBA9F1", "submission_order": 2, "result": "AC", "execution_time": "2720 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(int(math.log2(n-1))):\n        for j in range(2**(i+1)):\n            if (j+2**(i+1)) > (n-1): continue\n            qc.cx(j,j+2**(i+1))\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((0,2))\n    clist.append((1,3))\n    clist.append((1,4))\n    clist.append((2,5))\n    clist.append((2,6))\n    clist.append((3,7))\n    clist.append((3,8))\n    clist.append((4,9))\n    clist.append((4,10))\n    clist.append((5,11))\n    clist.append((5,12))\n    clist.append((6,13))\n    clist.append((6,14))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n        qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 2, "result": "DLE", "execution_time": "1126 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((0,2))\n    clist.append((1,3))\n    clist.append((1,4))\n    clist.append((2,5))\n    clist.append((2,6))\n    clist.append((3,7))\n    clist.append((3,8))\n    clist.append((4,9))\n    clist.append((4,10))\n    clist.append((5,11))\n    clist.append((5,12))\n    clist.append((6,13))\n    clist.append((6,14))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n            qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 3, "result": "WA", "execution_time": "1390 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((1,2))\n    clist.append((2,3))\n    clist.append((3,4))\n    clist.append((0,5))\n    clist.append((0,8))\n    clist.append((0,10))\n    clist.append((1,11))\n    clist.append((1,12))\n    clist.append((2,13))\n    clist.append((5,14))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n            qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 4, "result": "WA", "execution_time": "1171 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((0,5))\n    clist.append((0,8))\n    clist.append((0,10))\n    clist.append((1,2))\n    clist.append((1,11))\n    clist.append((1,12))\n    clist.append((2,3))\n    clist.append((2,13))\n    clist.append((3,4))\n    clist.append((5,14))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n            qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 5, "result": "WA", "execution_time": "1461 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((1,2))\n    clist.append((2,3))\n    clist.append((3,4))\n    clist.append((0,5))\n    clist.append((0,8))\n    clist.append((0,10))\n    clist.append((1,11))\n    clist.append((1,12))\n    clist.append((2,13))\n    clist.append((5,14))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n            qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 6, "result": "WA", "execution_time": "1377 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((0,5))\n    clist.append((0,8))\n    clist.append((0,10))\n    clist.append((1,2))\n    clist.append((1,11))\n    clist.append((1,12))\n    clist.append((2,3))\n    clist.append((2,13))\n    clist.append((3,4))\n    clist.append((5,14))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n            qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 7, "result": "RE", "execution_time": "1468 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((0,5))\n    clist.append((0,8))\n    clist.append((0,10))\n    clist.append((1,2))\n    clist.append((1,11))\n    clist.append((1,12))\n    clist.append((2,3))\n    clist.append((2,13))\n    clist.append((3,4))\n    clist.append((5,14))\n    clist.appned((8,9))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n            qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 8, "result": "WA", "execution_time": "1586 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((0,5))\n    clist.append((0,8))\n    clist.append((0,10))\n    clist.append((1,2))\n    clist.append((1,11))\n    clist.append((1,12))\n    clist.append((2,3))\n    clist.append((2,13))\n    clist.append((3,4))\n    clist.append((5,14))\n    clist.append((8,9))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n            qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A787ABE8A99D7", "submission_order": 9, "result": "AC", "execution_time": "2096 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = []\n    clist.append((0,1))\n    clist.append((1,2))\n    clist.append((2,3))\n    clist.append((3,4))\n    clist.append((0,5))\n    clist.append((5,6))\n    clist.append((6,7))\n    clist.append((0,8))\n    clist.append((8,9))\n    clist.append((0,10))\n    clist.append((1,11))\n    clist.append((1,12))\n    clist.append((2,13))\n    clist.append((5,14))\n\n    for c in clist:\n        if(c[0] < n and c[1] < n):\n            qc.cx(c[0], c[1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A7A4FF88CC34C", "submission_order": 1, "result": "AC", "execution_time": "1883 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        j = (1<<(i.bit_length()-1))\n        qc.cx(i-j,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A7A756D1D14CA", "submission_order": 1, "result": "AC", "execution_time": "2019 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    qc0 = QuantumCircuit(n-1)\n    for i in range(n-1):\n        qc0.x(i)\n    cxgates = qc0.to_gate().control(1)\n\n    qc.append(cxgates, range(n))\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A7AAEF6DDD82B", "submission_order": 1, "result": "AC", "execution_time": "2191 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.x(0)\n\tqc.h(0)\n\tl = 1\n\twhile l < n:\n\t\tr = min(n, 2 * l)\n\t\tfor i in range(l, r):\n\t\t\tqc.cx(i - l, i)\n\t\tl = r\n\treturn qc\n'''"}
{"problem": "QPC002_A5", "user": "A7EE3050B36EC", "submission_order": 1, "result": "AC", "execution_time": "2876 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.x(0)\n    qc.h(0)\n\n    controls = [0, 0, 1, 0, 1, 2, 3, 0, 1, 2, 3, 4, 5, 6, 7,]\n\n    for i in range(1, n):\n        qc.cx(controls[i - 1], i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A7F5AE0FCF428", "submission_order": 1, "result": "RE", "execution_time": "2022 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2 ** i + j == n:\n                break\n            qc.cx(j,2**i + j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A7F5AE0FCF428", "submission_order": 2, "result": "RE", "execution_time": "1548 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2 ** i + j == n:\n                break\n            qc.cx(j,2**i + j)\n    qc.barrier()\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A7F5AE0FCF428", "submission_order": 3, "result": "AC", "execution_time": "1824 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2 ** i + j == n:\n                break\n            qc.cx(j,2**i + j)\n    qc.barrier()\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A81F12C7D0386", "submission_order": 1, "result": "DLE", "execution_time": "1901 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m = 1\n    qc.h(0)\n    for i in range(5):\n        for l in range(i+1):\n            if m >= n:\n                break\n            qc.cx(l,m)\n            m += 1\n        if m >= n:\n            break\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A81F12C7D0386", "submission_order": 2, "result": "AC", "execution_time": "2163 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    m = 1\n    qc.h(0)\n    for i in range(5):\n        for l in range(2**i):\n            if m >= n:\n                break\n            qc.cx(l,m)\n            m += 1\n        if m >= n:\n            break\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8209E9E34AD3", "submission_order": 1, "result": "DLE", "execution_time": "1578 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(n):\n        if i*2+1<n:\n            qc.cx(i,i*2+1)\n            if i*2+2<n:\n                qc.cx(i,i*2+2)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8209E9E34AD3", "submission_order": 2, "result": "AC", "execution_time": "2123 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    t=7*math.pi/2\n    qc.ry(t,0)\n    li=[0]\n    nex=[0]\n    while len(li)<n:\n        nex=li.copy()\n        ma=max(li)+1\n        for i in li:\n            \n            if ma<n:\n                qc.cx(i,ma)\n                nex.append(ma)\n                ma+=1\n        \n        li=nex\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A84267D255FA3", "submission_order": 1, "result": "AC", "execution_time": "1670 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    d = 1\n    while d < n:\n        for i in range(0, d):\n            if i + d < n:\n                qc.cx(i, i + d)\n                print(i, i + d)\n        d *= 2\n    qc.z(0)\n\n    return qc\n\n# solve(15).draw('mpl').show()\n'''"}
{"problem": "QPC002_A5", "user": "A86DFF5705F98", "submission_order": 1, "result": "AC", "execution_time": "2305 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, n-1)\n\n    if n>=3:\n      qc.cx(0, 1)\n    if n>=4:\n      qc.cx(n-1, n-2)\n    if n>=5:\n      qc.cx(0, 2)\n    if n>=6:\n      qc.cx(n-1, n-3)\n    if n>=7:\n      qc.cx(1, 3)\n    if n>=8:\n      qc.cx(n-2, n-4)\n    if n>=9:\n      qc.cx(0, 4)\n    if n>=10:\n      qc.cx(n-1, n-5)\n    if n>=11:\n      qc.cx(1, 5)\n    if n>=12:\n      qc.cx(n-2, n-6)\n    if n>=13:\n      qc.cx(2, 6)\n    if n>=14:\n      qc.cx(n-3, n-7)\n    if n>=15:\n      qc.cx(n-4, n-8)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 1, "result": "DLE", "execution_time": "1321 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx(i//2, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 2, "result": "DLE", "execution_time": "1276 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//2, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 3, "result": "DLE", "execution_time": "1180 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//3, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 4, "result": "DLE", "execution_time": "1313 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//4, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 5, "result": "RE", "execution_time": "1134 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qg.cy(math.pi / 2.0, 0)\n    # qc.h(0)\n    # qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//2, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(math.pi / 2.0, 0)\n    # qc.h(0)\n    # qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(math.pi / 2.0, 0)\n    # qc.h(0)\n    # qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 8, "result": "WA", "execution_time": "1200 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(math.pi / 2.0, 0)\n    # qc.h(0)\n    # qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//2, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 9, "result": "DLE", "execution_time": "1256 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(-math.pi / 2.0, 0)\n    # qc.h(0)\n    # qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//2, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 10, "result": "DLE", "execution_time": "1164 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(-math.pi / 2.0, 0)\n    # qc.h(0)\n    # qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//3, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AB1A0CB5FB8", "submission_order": 11, "result": "DLE", "execution_time": "1329 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(-math.pi / 2.0, 0)\n    # qc.h(0)\n    # qc.z(0)\n    for i in range(1, n):\n        qc.cx((i-1)//2, i)\n        \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AED22894413", "submission_order": 1, "result": "DLE", "execution_time": "1745 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n // 2):\n        qc.cx(0, i)\n    for i in range(n - 2, n // 2 - 1, -1):\n        qc.cx(n - 1, i)\n    \n    qc.z(n - 1)\n        \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8AED22894413", "submission_order": 2, "result": "AC", "execution_time": "2555 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    entangled = [0]\n    next_qubit = 1\n    while next_qubit < n:\n        new_controls = []\n        for control in entangled:\n            if next_qubit < n:\n                qc.cx(control, next_qubit)\n                new_controls.append(next_qubit)\n                next_qubit += 1\n        entangled += new_controls\n    qc.z(n - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8FBA9AB14E2A", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n <= 5:\n        for i in range(n - ):\n            qc.cx(0, i + 1)\n    elif n <= 11:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n    elif n == 12:\n    elif n == 13:\n    elif n == 14:\n    elif n == 15:\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8FBA9AB14E2A", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n <= 5:\n        for i in range(n - ):\n            qc.cx(0, i + 1)\n    elif n <= 11:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n    elif n == 12:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 13:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 14:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n    elif n == 15:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n        qc.cx(14, 15)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8FBA9AB14E2A", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n <= 5:\n        for i in range(n - ):\n            qc.cx(0, i + 1)\n    elif n <= 11:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n    elif n == 12:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 13:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 14:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n    else:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n        qc.cx(14, 15)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8FBA9AB14E2A", "submission_order": 4, "result": "RE", "execution_time": "1337 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n <= 5:\n        for i in range(n - 1):\n            qc.cx(0, i + 1)\n    elif n <= 11:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n    elif n == 12:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 13:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 14:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n    else:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n        qc.cx(14, 15)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8FBA9AB14E2A", "submission_order": 5, "result": "DLE", "execution_time": "2682 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n <= 5:\n        for i in range(n - 1):\n            qc.cx(0, i + 1)\n    elif n <= 8:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n    elif n == 8:\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n    elif n == 9:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n    elif n == 10:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n    elif n == 11:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n    elif n == 12:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 13:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 14:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n    else:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8FBA9AB14E2A", "submission_order": 6, "result": "DLE", "execution_time": "1081 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n <= 3:\n        for i in range(n - 1):\n            qc.cx(0, i + 1)\n    elif n <= 8:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n    elif n == 8:\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n    elif n == 8:\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n    elif n == 9:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n    elif n == 10:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n    elif n == 11:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n    elif n == 12:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 13:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 14:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n    else:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8FBA9AB14E2A", "submission_order": 7, "result": "AC", "execution_time": "2458 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    if n <= 3:\n        for i in range(n - 1):\n            qc.cx(0, i + 1)\n    elif n <= 6:\n        half = n // 2\n        first = n - half - 1\n        for i in range(first):\n            qc.cx(0, i + 1)\n        for i in range(half):\n            qc.cx(1, i + 1 + first)\n    elif n == 7:\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n    elif n == 8:\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n    elif n == 8:\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n    elif n == 9:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n    elif n == 10:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n    elif n == 11:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n    elif n == 12:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 13:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n    elif n == 14:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n    else:\n        qc.cx(0, 8)\n        qc.cx(0, 4)\n        qc.cx(8, 12)\n        qc.cx(0, 2)\n        qc.cx(4, 6)\n        qc.cx(8, 10)\n        qc.cx(12, 14)\n        qc.cx(0, 1)\n        qc.cx(2, 3)\n        qc.cx(4, 5)\n        qc.cx(6, 7)\n        qc.cx(8, 9)\n        qc.cx(10, 11)\n        qc.cx(12, 13)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A8FD270DBAB40", "submission_order": 1, "result": "AC", "execution_time": "2203 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef rec(i: int, l: int, qc: QuantumCircuit):\n    qc.cx(i, i+l//2)\n    if l//2>1:\n        rec(i, l//2, qc)\n    if l-l//2>1:\n        rec(i+l//2, l-l//2, qc)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    rec(0, n, qc)\n    qc.cz(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A93CF0F37008F", "submission_order": 1, "result": "DLE", "execution_time": "1101 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,n-1)\n    if n%2 == 0:\n      for i in range(1, n//2):\n        qc.cx(0,i)\n        qc.cx(n-1,n-1-i)\n    else:\n      qc.cx(0,n//2)\n      for i in range(1, n//2):\n        qc.cx(0,i)\n        qc.cx(n-1,n-1-i)\n    qc.z(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A93CF0F37008F", "submission_order": 2, "result": "UGE", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.append(subsolve(n), range(n))\n    qc.z(n-1)\n    return qc\n\ndef subsolve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n      return qc\n    else:\n      qc.append(subsolve(n//2+n%2), range(n//2+n%2))\n      qc.append(subsolve(n//2), reversed(range(n//2+n%2,n)))\n      return qc\n'''"}
{"problem": "QPC002_A5", "user": "A93CF0F37008F", "submission_order": 3, "result": "WA", "execution_time": "1650 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.append(subsolve(n), range(n))\n    qc.z(n-1)\n    return qc.decompose()\n\ndef subsolve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n      return qc\n    else:\n      qc.append(subsolve(n//2+n%2), range(n//2+n%2))\n      qc.append(subsolve(n//2), reversed(range(n//2+n%2,n)))\n      return qc.decompose()\n'''"}
{"problem": "QPC002_A5", "user": "A99E124B4D58B", "submission_order": 1, "result": "AC", "execution_time": "1766 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    tmp = 0\n    lim = 1\n    for i in range(1,n):\n        qc.cx(tmp,i)\n        tmp += 1\n        if tmp == lim:\n            lim *= 2\n            tmp = 0\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A99E905975B3F", "submission_order": 1, "result": "AC", "execution_time": "1758 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for depth in range(4, -1, -1):\n        for i in range(0, n, 1<<(depth+1)):\n            if i+(1<<depth) < n:\n                qc.cx(i, i+(1<<depth))\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A9B4F159EEED2", "submission_order": 1, "result": "WA", "execution_time": "1146 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for b in range(1, 5):\n        for i in range(b):\n            if (1<<b)+i <= n-1:\n                qc.cx(i, (1<<b)+i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A9B4F159EEED2", "submission_order": 2, "result": "WA", "execution_time": "1192 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for b in range(5):\n        for i in range(b):\n            if (1<<b)+i <= n-1:\n                qc.cx(i, (1<<b)+i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A9B4F159EEED2", "submission_order": 3, "result": "AC", "execution_time": "2200 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    qc.z(0)\n    for b in range(6):\n        for i in range((1<<b)):\n            if (1<<b)+i <= n-1:\n                qc.cx(i, (1<<b)+i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A9C40888967A6", "submission_order": 1, "result": "WA", "execution_time": "1184 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef construct_optimal_tree(n):\n    def build_tree(start, end):\n        if start > end:\n            return []\n        mid = (start + end) // 2\n        left_subtree = build_tree(start, mid - 1)\n        right_subtree = build_tree(mid + 1, end)\n        \n        result = []\n        if mid - 1 >= start:\n            result.append((mid, (start + mid - 1) // 2))\n        if mid + 1 <= end:\n            result.append((mid, (mid + 1 + end) // 2))\n        \n        return result + right_subtree + left_subtree\n    \n    return build_tree(0, n - 1)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    vals = construct_optimal_tree(n)\n    mid = vals[0][0]\n    qc.h(0)\n    qc.z(0)\n    for (i, j) in vals:\n        qc.cx(i, j)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A9E43DBB56CB2", "submission_order": 1, "result": "AC", "execution_time": "1683 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    for m in range(n):\n        for k in range(2 ** m):\n            if ((2 ** m) + k) >= n: break\n            qc.cx(k, 2 ** m + k)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "A9F29C570D5F3", "submission_order": 1, "result": "RE", "execution_time": "1042 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n \n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j, 2**i + j)\n \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA17A5CD51E02", "submission_order": 1, "result": "WA", "execution_time": "1161 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply Hadamard gate to each qubit\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply a Z gate to the last qubit\n    qc.z(n-1)\n    \n    # We need to add a global phase of π to get the correct sign\n    # This can be achieved by using a multi-qubit controlled-Z gate\n    qc.cz(0, n-1)  # \n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA17A5CD51E02", "submission_order": 2, "result": "AC", "execution_time": "1984 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for b in reversed(range(5)):\n        i = 0\n        while True:\n            if i + (1<<b) >= n:\n                break\n            qc.cx(i, i + (1<<b))\n            i += (1<<(b+1))\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA3A2B37FE6CB", "submission_order": 1, "result": "AC", "execution_time": "1678 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    def cnot_(sta, end):\n        if sta >= end - 1:\n            return\n        mid = (sta + end) // 2\n        qc.cx(sta, mid)\n        cnot_(sta, mid)\n        cnot_(mid, end)\n\n    cnot_(0, n)\n\n    qc.z(0)\n\n    return qc\n\nsolve(15)\n'''"}
{"problem": "QPC002_A5", "user": "AA5403CC3F5E2", "submission_order": 1, "result": "WA", "execution_time": "1934 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    half = (n+1)//2\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, half):\n        if i % 2 == 0:\n            qc.cx(0, i)\n        else:\n            qc.cx(1, i)\n\n    for j in range(half, n):\n        qc.cx(j - half, j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA5403CC3F5E2", "submission_order": 2, "result": "WA", "execution_time": "1966 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    half = (n+1)//2\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, half):\n        if i % 2 == 0:\n            qc.cx(0, i)\n        else:\n            qc.cx(1, i)\n\n    for j in range(half, n):\n        qc.cx(j - half, j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA5403CC3F5E2", "submission_order": 3, "result": "DLE", "execution_time": "1912 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    half = (n+1)//2\n    qc.h(0)\n    for i in range(1, n):\n        val = int(math.log2(i) + 1)\n        qc.cx(i-val, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA5403CC3F5E2", "submission_order": 4, "result": "DLE", "execution_time": "1820 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    half = (n+1)//2\n    qc.h(0)\n    for i in range(1, n):\n        val = int(math.log2(i)) + 1\n        qc.cx(i-val, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA5403CC3F5E2", "submission_order": 5, "result": "WA", "execution_time": "1775 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    half = (n+1)//2\n    qc.h(0)\n    for i in range(1, n):\n        val = int(math.log2(i))\n        val = 2 ** val\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA5403CC3F5E2", "submission_order": 6, "result": "AC", "execution_time": "2167 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    half = (n+1)//2\n    qc.h(0)\n    for i in range(1, n):\n        val = int(math.log2(i))\n        val = 2 ** val\n        qc.cx(i-val, i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA5E44ECB7F91", "submission_order": 1, "result": "RE", "execution_time": "1848 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n    for i in range(3,n-1,3):\n        qc.cx(0,i)\n        qc.cx(1,i+1)\n        qc.cx(2,i+2)\n    if n%3==1:\n        qc.cx(0,n-1)\n    elif n%3==2:\n        qc.cx(0,n-1)\n        qc.cx(1,n-2)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA5E44ECB7F91", "submission_order": 2, "result": "WA", "execution_time": "1897 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i+j==n:\n                break\n            qc.cx(j,2**i+j)\n    qc.cx(0,1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AA5E44ECB7F91", "submission_order": 3, "result": "AC", "execution_time": "1942 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i+j==n:\n                break\n            qc.cx(j,2**i+j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AAC83A4DC9542", "submission_order": 1, "result": "AC", "execution_time": "2780 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, min(4, n)):\n        qc.cx(i - 2, i)\n    for i in range(4, min(8, n)):\n        qc.cx(i - 4, i)\n    for i in range(8, n):\n        qc.cx(i - 8, i)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AAF6CB6C243E0", "submission_order": 1, "result": "WA", "execution_time": "1520 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    old_entangled = [0, 1]\n    new_entangled = [i for i in old_entangled]\n    remaining = list(range(2, n))\n    while len(remaining) != 0: \n        for i in old_entangled:\n            tbe = remaining[-1]\n            qc.cx(i, tbe)\n            new_entangled.append(tbe)\n            remaining.pop()\n            if len(remaining) == 0:\n                break\n        old_entangled = [i for i in new_entangled]  \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AAF6CB6C243E0", "submission_order": 2, "result": "AC", "execution_time": "2135 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.cx(0, 1)\n    old_entangled = [0, 1]\n    new_entangled = [i for i in old_entangled]\n    remaining = list(range(2, n))\n    while len(remaining) != 0: \n        for i in old_entangled:\n            tbe = remaining[-1]\n            qc.cx(i, tbe)\n            new_entangled.append(tbe)\n            remaining.pop()\n            if len(remaining) == 0:\n                break\n        old_entangled = [i for i in new_entangled]  \n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB21B5C096AED", "submission_order": 1, "result": "RE", "execution_time": "2144 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j, 2**i + j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB21B5C096AED", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j, 2**i + )\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB21B5C096AED", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i + j == n:\n                break\n            qc.cx(j, 2**i + j)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB43FA1651163", "submission_order": 1, "result": "WA", "execution_time": "1231 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    if n%2 != 0:\n        e = n-1\n        o = n\n    else:\n        e = n\n        o = n-1\n\n    for i in range(0, e, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, o, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB43FA1651163", "submission_order": 2, "result": "WA", "execution_time": "1273 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    if n%2 != 0:\n        e = n-1\n        o = n\n    else:\n        e = n\n        o = n-1\n\n    for i in range(0, e, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, o, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB43FA1651163", "submission_order": 3, "result": "RE", "execution_time": "1638 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(n):\n        qc.h(i, i+1)\n\n    if n%2 != 0:\n        e = n-1\n        o = n\n    else:\n        e = n\n        o = n-1\n\n    for i in range(0, e, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, o, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB43FA1651163", "submission_order": 4, "result": "WA", "execution_time": "1141 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(n):\n        qc.h(i)\n\n    if n%2 != 0:\n        e = n-1\n        o = n\n    else:\n        e = n\n        o = n-1\n\n    for i in range(0, e, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, o, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB43FA1651163", "submission_order": 5, "result": "WA", "execution_time": "1190 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.x(i)\n\n    for i in range(1,n):\n        qc.x(i)\n\n    if n%2 != 0:\n        e = n-1\n        o = n\n    else:\n        e = n\n        o = n-1\n\n    for i in range(0, e, 2):\n        qc.cx(i, i+1)\n\n    for i in range(1, o, 2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB70508D27968", "submission_order": 1, "result": "AC", "execution_time": "1893 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for bit in range(1, n):\n        sb = bin(bit)[2:]\n        sb = '0'+sb[1:]\n        b = int(sb, 2)\n        qc.cx(b, bit)\n    qc.z(n-1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AB86B2F691C0D", "submission_order": 1, "result": "AC", "execution_time": "1920 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    hi = 1\n    while hi < n:\n        k = hi\n        for i in range(k):\n            if hi == n:\n                break\n            qc.cx(i, k+i)\n            hi += 1\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ABAC070355438", "submission_order": 1, "result": "DLE", "execution_time": "1124 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, range(1, n))\n    qc.cz(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ABE5429DE7777", "submission_order": 1, "result": "DLE", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(0, n - 1, 2):\n        if i + 2 < n:\n            qc.cx(i, i + 2)\n\n    for i in range(1, n - 1, 2):\n        if i + 2 < n:\n            qc.cx(i, i + 2)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ABE5429DE7777", "submission_order": 2, "result": "WA", "execution_time": "1536 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    clist = [\n    (0, 1), (1, 2), (2, 3), (3, 4), (0, 5),\n    (5, 6), (6, 7), (0, 8), (8, 9), (0, 10),\n    (1, 11), (1, 12), (2, 13), (5, 14)\n    ]\n    for c in clist:\n        if c[0] < n and c[1] < n:\n            qc.cx(c[0], c[1])\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ABE5429DE7777", "submission_order": 3, "result": "AC", "execution_time": "2342 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    clist = [\n    (0, 1), (1, 2), (2, 3), (3, 4), (0, 5),\n    (5, 6), (6, 7), (0, 8), (8, 9), (0, 10),\n    (1, 11), (1, 12), (2, 13), (5, 14)\n    ]\n    for c in clist:\n        if c[0] < n and c[1] < n:\n            qc.cx(c[0], c[1])\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ABE7E6F1C683C", "submission_order": 1, "result": "DLE", "execution_time": "1148 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    # 1/sqrt(2) * (|000...> + |100...>)\n    for i in range(1,n):\n        qc.cx(0, i)\n    # 1/sqrt(2) * (|000...> + |111...>)\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ABE7E6F1C683C", "submission_order": 2, "result": "AC", "execution_time": "2043 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    ok_cnt=1\n    nxt=1\n    \n    while nxt!=n:\n        tmp=0\n        for i in range(ok_cnt):\n            if nxt==n:\n                break\n            qc.cx(i,nxt)\n            nxt+=1\n            tmp+=1\n        ok_cnt+=tmp\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AC1CFA78AED1F", "submission_order": 1, "result": "RE", "execution_time": "1084 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        j=int(str(i)[3:])\n        qc.cx(j,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AC1CFA78AED1F", "submission_order": 2, "result": "RE", "execution_time": "1414 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        j=int(str(i)[3:],2)\n        qc.cx(j,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AC1CFA78AED1F", "submission_order": 3, "result": "AC", "execution_time": "2176 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(1,n):\n        j=i\n        for k in reversed(range(60)):\n            if (1<<k)&i:\n                j^=1<<k\n                break\n        qc.cx(j,i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AC21460462A33", "submission_order": 1, "result": "AC", "execution_time": "2289 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(4):\n        for j in range(2**i):\n            if j+2**i<n:\n                qc.cx(j, j+2**i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(7)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_A5", "user": "ACA38DA8BDED9", "submission_order": 1, "result": "DLE", "execution_time": "1167 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n >= 9:\n        qc.cx(0, 8)\n    if n >= 10:\n        qc.cx(8, 9)\n    if n >= 11:\n        qc.cx(8, 10)\n    if n >= 12:\n        qc.cx(10, 11)\n    if n >= 13:\n        qc.cx(8, 12)\n    if n >= 14:\n        qc.cx(12, 13)\n    if n >= 15:\n        qc.cx(12, 14)\n    if n >= 5:\n        qc.cx(0, 4)\n    if n >= 6:\n        qc.cx(4, 5)\n    if n >= 7:\n        qc.cx(4, 6)\n    if n >= 8:\n        qc.cx(6, 7)\n    if n >= 3:\n        qc.cx(0, 2)\n    if n >= 4:\n        qc.cx(2, 3)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ACA38DA8BDED9", "submission_order": 2, "result": "WA", "execution_time": "1318 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n >= 8:\n        qc.cx(0, 7)\n    if n >= 4:\n        qc.cx(0, 3)\n    if n >= 12:\n        qc.cx(7, 11)\n    if n >= 2:\n        qc.cx(0, 1)\n    if n >= 5:\n        qc.cx(3, 4)\n    if n >= 10:\n        qc.cx(7, 9)\n    if n >= 14:\n        qc.cx(11, 13)\n    if n >= 3:\n        qc.cx(1, 2)\n    if n >= 5:\n        qc.cx(3, 4)\n    if n >= 7:\n        qc.cx(5, 6)\n    if n >= 9:\n        qc.cx(7, 8)\n    if n >= 11:\n        qc.cx(9, 10)\n    if n >= 13:\n        qc.cx(11, 12)\n    if n == 15:\n        qc.cx(13, 14)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ACA38DA8BDED9", "submission_order": 3, "result": "AC", "execution_time": "2355 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    if n >= 8:\n        qc.cx(0, 7)\n    if n >= 4:\n        qc.cx(0, 3)\n    if n >= 12:\n        qc.cx(7, 11)\n    if n >= 2:\n        qc.cx(0, 1)\n    if n >= 6:\n        qc.cx(3, 5)\n    if n >= 10:\n        qc.cx(7, 9)\n    if n >= 14:\n        qc.cx(11, 13)\n    if n >= 3:\n        qc.cx(1, 2)\n    if n >= 5:\n        qc.cx(3, 4)\n    if n >= 7:\n        qc.cx(5, 6)\n    if n >= 9:\n        qc.cx(7, 8)\n    if n >= 11:\n        qc.cx(9, 10)\n    if n >= 13:\n        qc.cx(11, 12)\n    if n == 15:\n        qc.cx(13, 14)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ACB82131817AA", "submission_order": 1, "result": "AC", "execution_time": "2968 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    for r in (1, 2, 4, 8):\n        for i in range(r):\n            if i + r < n:\n                qc.cx(i, i + r)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ACD0B2091A3E2", "submission_order": 1, "result": "RE", "execution_time": "1618 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, min(4, n)):\n        qc.cx(i - 2, i)\n    for i in range(4, min(8, n)):\n        qc.cx(i - 4, i)\n    for i in range(8, n):\n        qc.cx(i - 8, i)\n\n    qc.z(0)\n'''"}
{"problem": "QPC002_A5", "user": "ACD0B2091A3E2", "submission_order": 2, "result": "RE", "execution_time": "1718 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, min(4, n)):\n        qc.cx(i - 2, i)\n    for i in range(4, min(8, n)):\n        qc.cx(i - 4, i)\n    for i in range(8, n):\n        qc.cx(i - 8, i)\n\n    return qc.z(0)\n'''"}
{"problem": "QPC002_A5", "user": "ACD0B2091A3E2", "submission_order": 3, "result": "AC", "execution_time": "1915 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    for i in range(2, min(4, n)):\n        qc.cx(i - 2, i)\n    for i in range(4, min(8, n)):\n        qc.cx(i - 4, i)\n    for i in range(8, n):\n        qc.cx(i - 8, i)\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ACDBA78AF7FCC", "submission_order": 1, "result": "AC", "execution_time": "2063 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    \n    step = 1\n    while step < n:\n\n        for i in range(step):\n            if step + i < n:\n                qc.cx(i, step + i)\n            else:\n                break\n\n        step *= 2\n\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ACDCAFBE20CA4", "submission_order": 1, "result": "AC", "execution_time": "1895 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    l = int(math.ceil(math.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n\n    qc.z(1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD09D51CB79DF", "submission_order": 1, "result": "DLE", "execution_time": "1292 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.cx((i - 1) // 2, i)\n    \n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD09D51CB79DF", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 8:\n        m = 4\n    elif n <= 8 && n > 4:\n        m = 3\n    elif n <= 4 && n > 2:\n        m = 2\n    else:\n        m = 1\n\n    qc.h(0)\n    for i in range(m):\n        for j in range(2 ** i):\n            if j + 2 ** (i + 1) < n:\n                qc.cx(j, j + 2 ** (i + 1))\n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD09D51CB79DF", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 8:\n        m = 4\n    elif n <= 8 && n > 4:\n        m = 3\n    elif n <= 4 && n > 2:\n        m = 2\n    else:\n        m = 1\n\n    qc.h(0)\n    for i in range(m):\n        for j in range(2 ** i):\n            if j + 2 ** i < n:\n                qc.cx(j, j + 2 ** i)\n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD09D51CB79DF", "submission_order": 4, "result": "WA", "execution_time": "1070 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_list = [0, 0, 1, 0, 1, 2, 3, 0, 1, 2, 3, 4, 5, 6]\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i, num_list[i - 1])\n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD09D51CB79DF", "submission_order": 5, "result": "AC", "execution_time": "2766 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    num_list = [0, 0, 1, 0, 1, 2, 3, 0, 1, 2, 3, 4, 5, 6]\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(num_list[i - 1], i)\n    qc.z(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD2FEC8C49A99", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    q=1\n    lagd=1\n    while(q<n):\n        for a in range (lagd, 0, -1):\n            if(q==n):\n                break\n            qc.cx(lagd-a,2*lagd-a)\n            q++\n    qc.crx(2*math.pi,0,1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD2FEC8C49A99", "submission_order": 2, "result": "WA", "execution_time": "1297 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    q=1\n    lagd=1\n    while(q<n):\n        for a in range (lagd, 0, -1):\n            if(q==n):\n                break\n            qc.cx(lagd-a, 2*lagd-a)\n            q = q+1\n        lagd = lagd+1\n    qc.crx(2*math.pi, 0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD2FEC8C49A99", "submission_order": 3, "result": "WA", "execution_time": "1152 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    q=1\n    lagd=1\n    while(q<n):\n        for a in range (lagd, 0, -1):\n            if(q==n):\n                break\n            qc.cx(lagd-a, 2*lagd-a)\n            q = q+1\n        lagd= lagd+1\n    qc.crz(2*math.pi, 0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD2FEC8C49A99", "submission_order": 4, "result": "AC", "execution_time": "2150 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    if(n>2):\n        qc.cx(0, 2)\n    if(n>3):\n        qc.cx(1, 3)\n    if(n>4):\n        qc.cx(0, 4)\n    if(n>5):\n        qc.cx(1, 5)\n    if(n>6):\n        qc.cx(2, 6)\n    if(n>7):\n        qc.cx(3, 7)\n    if(n>8):\n        qc.cx(0, 8)\n    if(n>9):\n        qc.cx(1, 9)\n    if(n>10):\n        qc.cx(2, 10)\n    if(n>11):\n        qc.cx(3, 11)\n    if(n>12):\n        qc.cx(4, 12)\n    if(n>13):\n        qc.cx(5, 13)\n    if(n>14):\n        qc.cx(6, 14)\n    \n    qc.crz(2*math.pi, 0, 1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD34A9B75A231", "submission_order": 1, "result": "AC", "execution_time": "2322 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(0)\n    \n    block_num = int(np.ceil(np.log2(n)))\n    \n    for i in range(block_num):\n        for j in range(2**i):\n            qc.cx(control_qubit=j, target_qubit=(2**i)+j)\n            if((2**i)+j == n-1):\n                break\n        qc.barrier()\n                \n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD372A1623F65", "submission_order": 1, "result": "AC", "execution_time": "2143 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.h(0)\n    if n < 6:\n        for i in range(1, n):\n            qc.cx(0, i)\n    else:\n         for i in range(1, 5):\n             qc.cx(0, i)\n         if n < 9:\n             for i in range(5, n):\n                 qc.cx(1, i)\n         else:\n             for i in range(5, 8):\n                 qc.cx(1, i)\n             if n < 11:\n                 for i in range(8, n):\n                     qc.cx(2, i)\n             else:\n                 for i in range(8, 10):\n                     qc.cx(2, i)\n                 if n > 10:\n                     qc.cx(5, 10)\n                 if n > 11:\n                     qc.cx(5, 11)\n                 if n > 12:\n                     qc.cx(3, 12)\n                 if n > 13:\n                     qc.cx(6, 13)\n                 if n > 14:\n                     qc.cx(8, 14)\n                 if n > 15:\n                     qc.cx(10, 15)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD48A9E457062", "submission_order": 1, "result": "AC", "execution_time": "2647 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  qc.x(0)\n  qc.h(0)\n  a = 1\n  while a < n:\n    for i in range(min(a, n - a)):\n      qc.cx(i, a + i)\n    a *= 2\n  return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD54153516394", "submission_order": 1, "result": "AC", "execution_time": "1842 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    idx = 1 # 次に設定するやつ\n    while idx<n:\n        for i in range(0,idx):\n            # 設定済みのところから\n            if idx+i==n:\n                break\n            qc.cx(i, idx+i)\n        idx *= 2\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD60ACB340521", "submission_order": 1, "result": "DLE", "execution_time": "1950 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i//2,i)\n    \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD60ACB340521", "submission_order": 2, "result": "RE", "execution_time": "2188 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i-2**int(math.log2(i)),i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AD60ACB340521", "submission_order": 3, "result": "AC", "execution_time": "2111 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(i-2**int(math.log2(i)),i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ADDF1F9691F58", "submission_order": 1, "result": "AC", "execution_time": "2366 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.z(0)\n    for w in range(4):\n        w = 1 << w\n        for i in range(w, w << 1):\n            if i < n:\n                qc.cx(i - w, i)\n \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ADF3F8552E289", "submission_order": 1, "result": "AC", "execution_time": "2030 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(math.ceil(math.log2(n))):\n        for j in range(2**i):\n            if 2**i+j == n:\n                break\n            qc.cx(j, 2**i+j)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "ADF6B9654E3DC", "submission_order": 1, "result": "AC", "execution_time": "2123 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)  # 0000 + 1000\n    for i in range(1, n):\n        j = 0\n        while 2 ** j <= i:\n            j += 1\n        assert j >= 1\n        j -= 1\n        assert 2 ** j <= i\n        i2 = i - 2 ** j\n        qc.cx(i2, i)\n    # 0000 + 111\n    qc.z(0)  # 0000 - 1111\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AE0609B41226E", "submission_order": 1, "result": "DLE", "execution_time": "1633 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx((i + 1) // 2 - 1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AE3005ACF0A88", "submission_order": 1, "result": "AC", "execution_time": "2209 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    end = 1\n    while end < n:\n        for left in range(end):\n            qc.cx(left, end)\n            end += 1\n            if end == n:\n                break\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AE4B813884240", "submission_order": 1, "result": "WA", "execution_time": "1140 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Use a binary tree structure to apply CNOT gates in layers\n    step = 1\n    while step < n:\n        for i in range(0, n - step, step * 2):\n            qc.cx(i, i + step)\n        step *= 2\n    \n    # Step 3: Apply Z gate to the first qubit to introduce phase difference\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AE4B813884240", "submission_order": 2, "result": "DLE", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Step 1: Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates in parallel to entangle the first qubit with all others\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Step 3: Apply a Z gate to the first qubit to introduce the phase difference\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AE8850F95022E", "submission_order": 1, "result": "AC", "execution_time": "1998 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n#from qiskit.quantum_info import Statevector\n\n\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    for i in range(1,4):\n        for j in range(1,2**i+1):\n            ind = 2**i + j - 1\n            if ind >= n:\n                break\n            qc.cx(ind-2**i,ind)\n    qc.cp(np.pi,0,n-1)\n    return qc\n\nqc = solve(5)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_A5", "user": "AE95166FC81FE", "submission_order": 1, "result": "AC", "execution_time": "2264 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    \n    def apply_cx_chain(qc, control, start, end):\n        if start < end:\n            mid = (start + end) // 2\n            qc.cx(control, mid)\n            apply_cx_chain(qc, control, start, mid)\n            apply_cx_chain(qc, mid, mid + 1, end)\n    \n    apply_cx_chain(qc, 0, 1, n)\n    \n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AF99F5C3096E3", "submission_order": 1, "result": "DLE", "execution_time": "1189 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i//2, i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AF99F5C3096E3", "submission_order": 2, "result": "AC", "execution_time": "2066 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(i - 2 ** (i.bit_length() - 1), i)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AFA80BECD7A01", "submission_order": 1, "result": "DLE", "execution_time": "1111 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.cx(i//2,i)\n    \n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AFA80BECD7A01", "submission_order": 2, "result": "RE", "execution_time": "1206 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for bit in range(n):\n        for i in range(5)[::-1]:\n            if bit >> i & 1:\n                idx = i\n                break\n        qc.cx(bit-(1<<idx),bit)\n    \n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AFA80BECD7A01", "submission_order": 3, "result": "AC", "execution_time": "1722 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for bit in range(1,n):\n        for i in range(5)[::-1]:\n            if bit >> i & 1:\n                idx = i\n                break\n        qc.cx(bit-(1<<idx),bit)\n    \n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AFDFCA01F01CD", "submission_order": 1, "result": "DLE", "execution_time": "1119 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mid = n//2\n    qc.x(mid)\n    qc.h(mid)\n    for i in range(mid)[::-1]:\n        qc.cx(i+1,i)\n    for i in range(mid, n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AFDFCA01F01CD", "submission_order": 2, "result": "RE", "execution_time": "1173 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    l = int(np.ceil(np.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n    return qc\n'''"}
{"problem": "QPC002_A5", "user": "AFDFCA01F01CD", "submission_order": 3, "result": "AC", "execution_time": "2218 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    l = int(np.ceil(np.log2(n)))\n    for m in range(l, 0, -1):\n        for k in range(0, n, 2 ** m):\n            if k + 2 ** (m - 1) >= n: continue\n            qc.cx(k, k + 2 ** (m - 1))\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A00D6204F16C1", "submission_order": 1, "result": "RE", "execution_time": "1028 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A00D6204F16C1", "submission_order": 2, "result": "WA", "execution_time": "1490 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(0,0,theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A00D6204F16C1", "submission_order": 3, "result": "WA", "execution_time": "1425 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(0, 0, theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A00D6204F16C1", "submission_order": 4, "result": "WA", "execution_time": "1091 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(0, 0, theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A00D6204F16C1", "submission_order": 5, "result": "WA", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A00D6204F16C1", "submission_order": 6, "result": "WA", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(PhaseGate(theta), [0])\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A00D6204F16C1", "submission_order": 7, "result": "WA", "execution_time": "1032 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A013BB6670C9B", "submission_order": 1, "result": "AC", "execution_time": "1684 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A055EEA170536", "submission_order": 1, "result": "WA", "execution_time": "1186 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(theta, 0, 0, 0)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A055EEA170536", "submission_order": 2, "result": "WA", "execution_time": "1127 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(0, theta, 0, 0)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A055EEA170536", "submission_order": 3, "result": "AC", "execution_time": "1606 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.u(0, theta, 0, 0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A059123E0D3A8", "submission_order": 1, "result": "RE", "execution_time": "1049 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(thetha,0,0,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A059123E0D3A8", "submission_order": 2, "result": "RE", "execution_time": "1399 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(thetha,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A059123E0D3A8", "submission_order": 3, "result": "RE", "execution_time": "1332 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(thetha,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A059123E0D3A8", "submission_order": 4, "result": "RE", "execution_time": "1086 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(thetha,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A059123E0D3A8", "submission_order": 5, "result": "RE", "execution_time": "1051 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rx(thetha,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A059123E0D3A8", "submission_order": 6, "result": "RE", "execution_time": "1098 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(thetha,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A063194E4066B", "submission_order": 1, "result": "AC", "execution_time": "1847 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A096F9BD98202", "submission_order": 1, "result": "RE", "execution_time": "1039 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    ex = np.exp(1j * theta)\n    qc = ex*qc\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A096F9BD98202", "submission_order": 2, "result": "WA", "execution_time": "1341 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    \n    qc.rz(theta, 0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A096F9BD98202", "submission_order": 3, "result": "RE", "execution_time": "1097 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    \n    qc.u1(theta, 0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A096F9BD98202", "submission_order": 4, "result": "RE", "execution_time": "1071 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    \n    qc.u1(theta, 0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A096F9BD98202", "submission_order": 5, "result": "AC", "execution_time": "1413 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    \n    qc.rz(-2*theta, 0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A09C3AE2F8E57", "submission_order": 1, "result": "WA", "execution_time": "1108 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A09C3AE2F8E57", "submission_order": 2, "result": "AC", "execution_time": "1526 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0CAEAECEFD72", "submission_order": 1, "result": "WA", "execution_time": "1509 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0CAEAECEFD72", "submission_order": 2, "result": "WA", "execution_time": "1505 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0CAEAECEFD72", "submission_order": 3, "result": "WA", "execution_time": "1191 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta*2, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0CAEAECEFD72", "submission_order": 4, "result": "WA", "execution_time": "1066 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0CAEAECEFD72", "submission_order": 5, "result": "WA", "execution_time": "1276 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta*2, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0CAEAECEFD72", "submission_order": 6, "result": "RE", "execution_time": "1315 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(4*math.pi-theta*2, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0CAEAECEFD72", "submission_order": 7, "result": "RE", "execution_time": "1155 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(*math.pi-theta*2, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F3B24FBB6B9", "submission_order": 1, "result": "RE", "execution_time": "1044 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.P(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F3B24FBB6B9", "submission_order": 2, "result": "WA", "execution_time": "1154 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F3B24FBB6B9", "submission_order": 3, "result": "WA", "execution_time": "1056 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F3B24FBB6B9", "submission_order": 4, "result": "WA", "execution_time": "1106 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta/2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F3B24FBB6B9", "submission_order": 5, "result": "AC", "execution_time": "1606 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F790ECDE9D2", "submission_order": 1, "result": "AC", "execution_time": "2358 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F99F27C0985", "submission_order": 1, "result": "RE", "execution_time": "1121 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(math.pi, theta)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F99F27C0985", "submission_order": 2, "result": "RE", "execution_time": "1074 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(180, theta*180/math.pi)\n    qc.x()\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F99F27C0985", "submission_order": 3, "result": "WA", "execution_time": "1390 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(math.pi, 0)\n    qc.rz(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F99F27C0985", "submission_order": 4, "result": "WA", "execution_time": "1211 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(math.pi, 0)\n    qc.rx(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F99F27C0985", "submission_order": 5, "result": "WA", "execution_time": "1027 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*math.pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0F99F27C0985", "submission_order": 6, "result": "AC", "execution_time": "1428 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A0FDF4ABE955D", "submission_order": 1, "result": "AC", "execution_time": "1415 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import GlobalPhaseGate\nimport math\ndef solve(theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(1)\n  qc.append(GlobalPhaseGate(theta))\n  return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1014557B5B0B", "submission_order": 1, "result": "WA", "execution_time": "1161 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    qc.x(0)\n    qc.ry(theta, 0)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1014557B5B0B", "submission_order": 2, "result": "AC", "execution_time": "1928 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1093D7E7DBC0", "submission_order": 1, "result": "RE", "execution_time": "1853 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(GlobalPhaseGate(theta),range(1))\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1093D7E7DBC0", "submission_order": 2, "result": "AC", "execution_time": "2046 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(GlobalPhaseGate(theta))\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 1, "result": "WA", "execution_time": "1174 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 2, "result": "WA", "execution_time": "1043 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 3, "result": "WA", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)\n    qc.u(0, 0, theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 4, "result": "WA", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)\n    qc.u(0, 0, 2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 5, "result": "WA", "execution_time": "1245 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)\n    qc.u(2*theta, 0, 0, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 6, "result": "WA", "execution_time": "1044 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  # 1量子ビットの量子回路を作成  \n    qc.rz(2 * theta, 0)  # 位相を追加する  \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 7, "result": "WA", "execution_time": "1568 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  # 1量子ビットの量子回路を作成  \n    qc.rz(theta, 0)  # 位相を追加する  \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 8, "result": "WA", "execution_time": "1237 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  # 1量子ビットの量子回路を作成  \n    qc.u(2*theta, 0, 0, 0)  # 位相を追加する  \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 9, "result": "WA", "execution_time": "1399 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  # 1量子ビットの量子回路を作成  \n    qc.rx(2*theta, 0)  # 位相を追加する  \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 10, "result": "WA", "execution_time": "1137 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  \n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  \n    qc.rz(theta, 0)  \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 11, "result": "WA", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  \n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  \n    qc.ry(theta, 0)  \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 12, "result": "WA", "execution_time": "1056 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  # 1量子ビットの量子回路を作成  \n    qc.r(2*theta, 0, 0)  # 位相を追加する  \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 13, "result": "WA", "execution_time": "1284 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  # 1量子ビットの量子回路を作成  \n    qc.y(0)  # 位相を追加する  \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 14, "result": "WA", "execution_time": "1013 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  # 1量子ビットの量子回路を作成  \n    qc.y(0)  # 位相を追加する\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A131F05C78A13", "submission_order": 15, "result": "AC", "execution_time": "1621 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  # 1量子ビットの量子回路を作成  \n    qc.x(0)\n    qc.p(theta, 0)  # 位相を追加する\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A17E5A1A3CD3A", "submission_order": 1, "result": "RE", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(math.pi/2.0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A17E5A1A3CD3A", "submission_order": 2, "result": "WA", "execution_time": "1098 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(math.pi/2.0, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A17E5A1A3CD3A", "submission_order": 3, "result": "WA", "execution_time": "1061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A17E5A1A3CD3A", "submission_order": 4, "result": "WA", "execution_time": "1043 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A17E5A1A3CD3A", "submission_order": 5, "result": "WA", "execution_time": "1032 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F44C6438335", "submission_order": 1, "result": "WA", "execution_time": "1557 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F44C6438335", "submission_order": 2, "result": "WA", "execution_time": "1239 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F44C6438335", "submission_order": 3, "result": "WA", "execution_time": "1032 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta*2, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F44C6438335", "submission_order": 4, "result": "AC", "execution_time": "1605 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta*-2, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F4E5B9C4D6C", "submission_order": 1, "result": "WA", "execution_time": "1057 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 1, "result": "WA", "execution_time": "1192 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 2, "result": "WA", "execution_time": "1040 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 3, "result": "WA", "execution_time": "1607 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta/(2*math.pi)*360, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 4, "result": "WA", "execution_time": "1520 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-theta/(2*np.pi)*360, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 5, "result": "WA", "execution_time": "1236 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta/(2*np.pi)*360, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 6, "result": "WA", "execution_time": "1060 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 7, "result": "WA", "execution_time": "1247 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rx(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 8, "result": "WA", "execution_time": "1133 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.ry(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 9, "result": "WA", "execution_time": "1487 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.ry(2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 10, "result": "WA", "execution_time": "1037 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 11, "result": "RE", "execution_time": "1061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.r(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A1F8EA4EF042F", "submission_order": 12, "result": "AC", "execution_time": "1424 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A20D23332A815", "submission_order": 1, "result": "RE", "execution_time": "1120 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A20D23332A815", "submission_order": 2, "result": "WA", "execution_time": "1112 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A20D23332A815", "submission_order": 3, "result": "WA", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(0, 0, theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 1, "result": "WA", "execution_time": "1005 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 2, "result": "WA", "execution_time": "1087 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 3, "result": "WA", "execution_time": "1399 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 4, "result": "RE", "execution_time": "1088 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.GlobalPhaseGate(0)\n    qc.ry(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 5, "result": "RE", "execution_time": "1087 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1,'q',0)\n    # Write your code here:\n    qc.ry(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 6, "result": "WA", "execution_time": "1085 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1,0)\n    # Write your code here:\n    qc.ry(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 7, "result": "RE", "execution_time": "1698 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1,0)\n    # Write your code here:\n    qc.phase(theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 8, "result": "RE", "execution_time": "1196 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.phase(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 9, "result": "RE", "execution_time": "1399 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.phase(0,theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A21DB699D9994", "submission_order": 10, "result": "AC", "execution_time": "1869 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = theta\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A23C65FFCF45F", "submission_order": 1, "result": "WA", "execution_time": "1245 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A23C65FFCF45F", "submission_order": 2, "result": "AC", "execution_time": "1569 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A24777ADBDACB", "submission_order": 1, "result": "AC", "execution_time": "1983 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2651B60E50CE", "submission_order": 1, "result": "RE", "execution_time": "1208 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2651B60E50CE", "submission_order": 2, "result": "AC", "execution_time": "1469 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = theta\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2A765035C552", "submission_order": 1, "result": "AC", "execution_time": "1627 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = theta\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2DDCB4AF0C43", "submission_order": 1, "result": "WA", "execution_time": "1612 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2DDCB4AF0C43", "submission_order": 2, "result": "AC", "execution_time": "1516 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2E11DAE995FC", "submission_order": 1, "result": "WA", "execution_time": "1075 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2E11DAE995FC", "submission_order": 2, "result": "WA", "execution_time": "1500 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2E11DAE995FC", "submission_order": 3, "result": "WA", "execution_time": "1428 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2E11DAE995FC", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz.(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2E11DAE995FC", "submission_order": 5, "result": "AC", "execution_time": "1562 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 1, "result": "WA", "execution_time": "1118 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 2, "result": "RE", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.u1(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 3, "result": "WA", "execution_time": "1021 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 4, "result": "RE", "execution_time": "1092 ms", "memory": "140 MiB", "code": "'''python\ndef rotate(qc,p0):\n    theta=math.acos(p0*2-1)\n    qc.ry(theta,0)\n\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    rotate(qc, theta)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 5, "result": "RE", "execution_time": "1200 ms", "memory": "140 MiB", "code": "'''python\ndef rotate(qc,p0):\n    import math\n    theta=math.acos(p0*2-1)\n    qc.ry(theta,0)\n\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    rotate(qc, theta)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 6, "result": "WA", "execution_time": "1285 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.ry(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 7, "result": "RE", "execution_time": "1115 ms", "memory": "140 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    theta=math.acos(theta*2-1)\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 8, "result": "RE", "execution_time": "1227 ms", "memory": "141 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    theta=math.acos(thet*2)\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 9, "result": "RE", "execution_time": "1813 ms", "memory": "140 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    theta=math.acos(thet*2)\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 10, "result": "RE", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    theta=math.acos(theta*2)\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 11, "result": "WA", "execution_time": "1103 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 12, "result": "WA", "execution_time": "1069 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.rz(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A2F2DA0842D04", "submission_order": 13, "result": "AC", "execution_time": "1478 ms", "memory": "140 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.p(theta,0)\n    qc.global_phase = theta\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A36CDD0FDC886", "submission_order": 1, "result": "WA", "execution_time": "1380 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.rz(theta,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A36CDD0FDC886", "submission_order": 2, "result": "WA", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.rz(-theta,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A36CDD0FDC886", "submission_order": 3, "result": "AC", "execution_time": "1634 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.rz(2*theta,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A3871B421355B", "submission_order": 1, "result": "AC", "execution_time": "1897 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase += theta\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A39BDF7FD6083", "submission_order": 1, "result": "RE", "execution_time": "1397 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A39BDF7FD6083", "submission_order": 2, "result": "WA", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A39BDF7FD6083", "submission_order": 3, "result": "AC", "execution_time": "1561 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A3E0E89EF3479", "submission_order": 1, "result": "WA", "execution_time": "1398 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A3E0E89EF3479", "submission_order": 2, "result": "WA", "execution_time": "1362 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(-theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A3E0E89EF3479", "submission_order": 3, "result": "WA", "execution_time": "1355 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A3E0E89EF3479", "submission_order": 4, "result": "RE", "execution_time": "1024 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.u1(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A3E0E89EF3479", "submission_order": 5, "result": "RE", "execution_time": "1144 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.U1gate(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A3E0E89EF3479", "submission_order": 6, "result": "AC", "execution_time": "1430 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A40D5FB72BC59", "submission_order": 1, "result": "AC", "execution_time": "1899 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4109F6D75C09", "submission_order": 1, "result": "RE", "execution_time": "1353 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(-2*theta)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4109F6D75C09", "submission_order": 2, "result": "WA", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4109F6D75C09", "submission_order": 3, "result": "WA", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4109F6D75C09", "submission_order": 4, "result": "AC", "execution_time": "1439 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A42A651DDCE3F", "submission_order": 1, "result": "AC", "execution_time": "2018 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A43A67BECA670", "submission_order": 1, "result": "WA", "execution_time": "1060 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A43A67BECA670", "submission_order": 2, "result": "WA", "execution_time": "1067 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A43A67BECA670", "submission_order": 3, "result": "RE", "execution_time": "1135 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(np.theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A45AC8436FAC9", "submission_order": 1, "result": "AC", "execution_time": "1573 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(-2*theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A464A2BCE3BE9", "submission_order": 1, "result": "WA", "execution_time": "1481 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A464A2BCE3BE9", "submission_order": 2, "result": "WA", "execution_time": "1350 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A464A2BCE3BE9", "submission_order": 3, "result": "WA", "execution_time": "1013 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A464A2BCE3BE9", "submission_order": 4, "result": "WA", "execution_time": "1043 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A464A2BCE3BE9", "submission_order": 5, "result": "WA", "execution_time": "1074 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A464A2BCE3BE9", "submission_order": 6, "result": "WA", "execution_time": "1068 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A464A2BCE3BE9", "submission_order": 7, "result": "AC", "execution_time": "1388 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4BA844EE01D0", "submission_order": 1, "result": "RE", "execution_time": "1543 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4BA844EE01D0", "submission_order": 2, "result": "RE", "execution_time": "1322 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0,theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4BA844EE01D0", "submission_order": 3, "result": "WA", "execution_time": "1132 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4BA844EE01D0", "submission_order": 4, "result": "AC", "execution_time": "1393 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4C29EB0ECA1B", "submission_order": 1, "result": "AC", "execution_time": "1737 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4C6A1791385F", "submission_order": 1, "result": "WA", "execution_time": "1341 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4C6A1791385F", "submission_order": 2, "result": "WA", "execution_time": "1391 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta/2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4C6A1791385F", "submission_order": 3, "result": "WA", "execution_time": "1379 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(np.pi, theta, np.pi + theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4C6A1791385F", "submission_order": 4, "result": "AC", "execution_time": "1598 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4D72477E3115", "submission_order": 1, "result": "AC", "execution_time": "1473 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4E9F2E9050E1", "submission_order": 1, "result": "RE", "execution_time": "1448 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4E9F2E9050E1", "submission_order": 2, "result": "RE", "execution_time": "1792 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(0,-2*theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4E9F2E9050E1", "submission_order": 3, "result": "RE", "execution_time": "1669 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(0,2*theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4E9F2E9050E1", "submission_order": 4, "result": "RE", "execution_time": "1671 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(0,-2*theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A4E9F2E9050E1", "submission_order": 5, "result": "AC", "execution_time": "1879 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A504DAA804F5D", "submission_order": 1, "result": "WA", "execution_time": "1132 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A504DAA804F5D", "submission_order": 2, "result": "WA", "execution_time": "1037 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A504DAA804F5D", "submission_order": 3, "result": "WA", "execution_time": "1053 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A504DAA804F5D", "submission_order": 4, "result": "AC", "execution_time": "1612 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A51B089192FDF", "submission_order": 1, "result": "WA", "execution_time": "1112 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A51B089192FDF", "submission_order": 2, "result": "WA", "execution_time": "1016 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A51B089192FDF", "submission_order": 3, "result": "RE", "execution_time": "1049 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.r(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A51B089192FDF", "submission_order": 4, "result": "AC", "execution_time": "1446 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A5442D79A8C1B", "submission_order": 1, "result": "WA", "execution_time": "1464 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A5442D79A8C1B", "submission_order": 2, "result": "WA", "execution_time": "1086 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A5442D79A8C1B", "submission_order": 3, "result": "AC", "execution_time": "1441 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A560CDAFD1747", "submission_order": 1, "result": "AC", "execution_time": "1541 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A585A0D33E937", "submission_order": 1, "result": "RE", "execution_time": "1371 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.p(theta)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A59D3F721DACE", "submission_order": 1, "result": "AC", "execution_time": "1835 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta*2,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A5C924F4FCAFA", "submission_order": 1, "result": "AC", "execution_time": "1162 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A5EF417ECB27A", "submission_order": 1, "result": "RE", "execution_time": "2273 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta = float(input())\n    qc.rz(-theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A5EF417ECB27A", "submission_order": 2, "result": "WA", "execution_time": "1851 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A5EF417ECB27A", "submission_order": 3, "result": "WA", "execution_time": "2598 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A5EF417ECB27A", "submission_order": 4, "result": "AC", "execution_time": "2528 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A632770FF8909", "submission_order": 1, "result": "AC", "execution_time": "1436 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A63FD9A8A10F9", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    def solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta)\n\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A63FD9A8A10F9", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    def solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A63FD9A8A10F9", "submission_order": 3, "result": "AC", "execution_time": "1619 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta,  0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A64CD187EAC45", "submission_order": 1, "result": "WA", "execution_time": "1171 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A64CD187EAC45", "submission_order": 2, "result": "AC", "execution_time": "1403 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A689BE4353252", "submission_order": 1, "result": "RE", "execution_time": "1047 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.append(PhaseGate(theta))\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A689BE4353252", "submission_order": 2, "result": "WA", "execution_time": "1100 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A689BE4353252", "submission_order": 3, "result": "AC", "execution_time": "2000 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(2*theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A6AA3CF51AF31", "submission_order": 1, "result": "WA", "execution_time": "1565 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.ry(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A6AA3CF51AF31", "submission_order": 2, "result": "AC", "execution_time": "1687 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A6EFBDA075FC5", "submission_order": 1, "result": "WA", "execution_time": "1457 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.ry(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A6EFBDA075FC5", "submission_order": 2, "result": "WA", "execution_time": "1583 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.ry(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A6EFBDA075FC5", "submission_order": 3, "result": "RE", "execution_time": "1527 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.ry(0,theta)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A6EFBDA075FC5", "submission_order": 4, "result": "WA", "execution_time": "1490 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rx(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A6EFBDA075FC5", "submission_order": 5, "result": "WA", "execution_time": "1556 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A6EFBDA075FC5", "submission_order": 6, "result": "AC", "execution_time": "1571 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7633D15B3135", "submission_order": 1, "result": "AC", "execution_time": "1496 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A787FF10C2CBA", "submission_order": 1, "result": "AC", "execution_time": "1586 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 1, "result": "RE", "execution_time": "1100 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 2, "result": "RE", "execution_time": "1103 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 3, "result": "WA", "execution_time": "1514 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 4, "result": "WA", "execution_time": "1256 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 5, "result": "WA", "execution_time": "1148 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 6, "result": "WA", "execution_time": "1248 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta*2,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 7, "result": "WA", "execution_time": "1162 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta/2,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 8, "result": "WA", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A78E488496B01", "submission_order": 9, "result": "AC", "execution_time": "1617 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta*2,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7A2DFC0C5D19", "submission_order": 1, "result": "AC", "execution_time": "1591 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7ADA30C0D794", "submission_order": 1, "result": "AC", "execution_time": "1373 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7ADC4DFA2C02", "submission_order": 1, "result": "WA", "execution_time": "1127 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7ADC4DFA2C02", "submission_order": 2, "result": "AC", "execution_time": "1846 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7CCE07C86EA2", "submission_order": 1, "result": "WA", "execution_time": "1111 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7CCE07C86EA2", "submission_order": 2, "result": "WA", "execution_time": "1181 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.h(0)\n\n    qc.p(theta, 0)\n\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7CCE07C86EA2", "submission_order": 3, "result": "WA", "execution_time": "1241 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7CCE07C86EA2", "submission_order": 4, "result": "WA", "execution_time": "1086 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7CCE07C86EA2", "submission_order": 5, "result": "AC", "execution_time": "1518 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.global_phase = theta\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 1, "result": "RE", "execution_time": "1835 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 2, "result": "RE", "execution_time": "1151 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(0)\n    qc.p(0)\n    qc.p(0)\n    qc.p(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 3, "result": "RE", "execution_time": "1369 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(0)\n    qc.p(0)\n    qc.p(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 4, "result": "RE", "execution_time": "1319 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(0)\n    qc.p(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 5, "result": "WA", "execution_time": "1049 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.t(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 6, "result": "WA", "execution_time": "1061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.t(0)\n    qc.t(0)\n    qc.t(0)\n    qc.t(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 7, "result": "RE", "execution_time": "1046 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2 * pai , 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 8, "result": "WA", "execution_time": "1046 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 9, "result": "WA", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 10, "result": "WA", "execution_time": "1148 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 11, "result": "WA", "execution_time": "1139 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7D8F5D03453B", "submission_order": 12, "result": "AC", "execution_time": "1456 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math \n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7EB8671F30D1", "submission_order": 1, "result": "WA", "execution_time": "1107 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7EB8671F30D1", "submission_order": 2, "result": "WA", "execution_time": "1216 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta, 0)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A7EB8671F30D1", "submission_order": 3, "result": "AC", "execution_time": "1519 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 1, "result": "WA", "execution_time": "1214 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 2, "result": "WA", "execution_time": "1158 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 3, "result": "RE", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(-theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 4, "result": "WA", "execution_time": "1059 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 5, "result": "RE", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.t(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 6, "result": "WA", "execution_time": "1165 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    num_repeats = int(theta / (math.pi / 4))\n    remainder = theta % (math.pi / 4)\n    for _ in range(num_repeats):\n        qc.t(0)\n    if remainder > 0:\n        qc.t(0)\n        qc.h(0)\n        qc.t(0)\n        qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 7, "result": "WA", "execution_time": "1095 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 8, "result": "WA", "execution_time": "1069 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    num_repeats = int(theta / (math.pi / 4))\n    remainder = theta % (math.pi / 4)\n    for _ in range(num_repeats):\n        qc.t(0)\n    if remainder > 0:\n        qc.rz(remainder, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 9, "result": "WA", "execution_time": "1113 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 10, "result": "WA", "execution_time": "1057 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A832177F5156F", "submission_order": 11, "result": "AC", "execution_time": "1532 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A838CC8504008", "submission_order": 1, "result": "AC", "execution_time": "1511 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A84FA1084EC5B", "submission_order": 1, "result": "AC", "execution_time": "2124 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8503F4C830E5", "submission_order": 1, "result": "AC", "execution_time": "1485 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A86D4777C5D56", "submission_order": 1, "result": "WA", "execution_time": "1089 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A86D4777C5D56", "submission_order": 2, "result": "AC", "execution_time": "1394 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A86D902989BE1", "submission_order": 1, "result": "WA", "execution_time": "1195 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta =3.14\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A86D902989BE1", "submission_order": 2, "result": "WA", "execution_time": "1316 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta =1.57\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 1, "result": "WA", "execution_time": "1174 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 2, "result": "WA", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    import numpy as np\n    theta = np.pi /4\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 3, "result": "WA", "execution_time": "1228 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 4, "result": "WA", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 5, "result": "WA", "execution_time": "1356 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 6, "result": "WA", "execution_time": "1168 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 7, "result": "WA", "execution_time": "1186 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 8, "result": "WA", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 9, "result": "RE", "execution_time": "1285 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 10, "result": "TLE", "execution_time": "2000 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 11, "result": "WA", "execution_time": "1428 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A878BFA1E8C41", "submission_order": 12, "result": "AC", "execution_time": "1413 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A88ACCEA1618F", "submission_order": 1, "result": "AC", "execution_time": "1579 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.u(0, theta, 0, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A88E1302CD0C4", "submission_order": 1, "result": "RE", "execution_time": "1687 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta) -> QuantumCircuit:\n\tqc = QuantumCircuit(1)\n\tqc.x(0)\n\tqc.p(theta)\n\tqc.x(0)\n\treturn qc\n'''"}
{"problem": "QPC002_B1", "user": "A88E1302CD0C4", "submission_order": 2, "result": "AC", "execution_time": "2336 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta) -> QuantumCircuit:\n\tqc = QuantumCircuit(1)\n\tqc.x(0)\n\tqc.p(theta, 0)\n\tqc.x(0)\n\treturn qc\n'''"}
{"problem": "QPC002_B1", "user": "A892097DB49B2", "submission_order": 1, "result": "WA", "execution_time": "1054 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A892097DB49B2", "submission_order": 2, "result": "AC", "execution_time": "1407 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(-2 * theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A89DDF4696E26", "submission_order": 1, "result": "AC", "execution_time": "2259 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.append(PhaseGate(theta), [0])\n    qc.x(0)\n\n    return qc\n\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(0.5)\n#     sv = Statevector(qc)\n#     print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_B1", "user": "A8B77F396ED02", "submission_order": 1, "result": "WA", "execution_time": "1567 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8B77F396ED02", "submission_order": 2, "result": "AC", "execution_time": "1487 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8BAAEB75C63B", "submission_order": 1, "result": "AC", "execution_time": "1460 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8BB3962ADCA1", "submission_order": 1, "result": "WA", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8BB3962ADCA1", "submission_order": 2, "result": "WA", "execution_time": "1145 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(0, 0, theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8BB3962ADCA1", "submission_order": 3, "result": "AC", "execution_time": "1664 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = theta\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8DB711576186", "submission_order": 1, "result": "WA", "execution_time": "1091 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8DB711576186", "submission_order": 2, "result": "RE", "execution_time": "1491 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(thet,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8DB711576186", "submission_order": 3, "result": "WA", "execution_time": "1043 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8DB711576186", "submission_order": 4, "result": "WA", "execution_time": "1319 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-1*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8DB711576186", "submission_order": 5, "result": "WA", "execution_time": "1011 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8DB711576186", "submission_order": 6, "result": "WA", "execution_time": "1164 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8DB711576186", "submission_order": 7, "result": "AC", "execution_time": "1410 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8E6316AF4432", "submission_order": 1, "result": "WA", "execution_time": "1479 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A8E6316AF4432", "submission_order": 2, "result": "AC", "execution_time": "1619 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A932FCAA6B64A", "submission_order": 1, "result": "WA", "execution_time": "1039 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    qc.z(0)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A9405FB0A1DE0", "submission_order": 1, "result": "RE", "execution_time": "1088 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A9405FB0A1DE0", "submission_order": 2, "result": "AC", "execution_time": "1533 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A960A3071AECC", "submission_order": 1, "result": "WA", "execution_time": "1073 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A960A3071AECC", "submission_order": 2, "result": "WA", "execution_time": "1124 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A960A3071AECC", "submission_order": 3, "result": "WA", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A960A3071AECC", "submission_order": 4, "result": "WA", "execution_time": "1049 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A960A3071AECC", "submission_order": 5, "result": "WA", "execution_time": "1099 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A960A3071AECC", "submission_order": 6, "result": "RE", "execution_time": "1073 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A960A3071AECC", "submission_order": 7, "result": "AC", "execution_time": "1435 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A99D9CC6713DA", "submission_order": 1, "result": "RE", "execution_time": "1102 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.u1(theta, 0)  # Apply the phase shift U1 gate\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A99D9CC6713DA", "submission_order": 2, "result": "WA", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(theta, 0)  # Apply the phase shift Rz gate\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A99D9CC6713DA", "submission_order": 3, "result": "AC", "execution_time": "1541 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.global_phase = theta  # Set the global phase to theta\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A9B8D3BD66F96", "submission_order": 1, "result": "AC", "execution_time": "1524 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta *= 2\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A9C2D25002BD3", "submission_order": 1, "result": "AC", "execution_time": "1796 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta,  0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A9E786583944A", "submission_order": 1, "result": "WA", "execution_time": "1431 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u(2*theta, math.pi/2, 0, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A9E786583944A", "submission_order": 2, "result": "WA", "execution_time": "1257 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(2*theta, 0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "A9E786583944A", "submission_order": 3, "result": "AC", "execution_time": "1423 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA144A6BCBE02", "submission_order": 1, "result": "WA", "execution_time": "1053 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA144A6BCBE02", "submission_order": 2, "result": "AC", "execution_time": "1748 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: int) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA25505C6DC45", "submission_order": 1, "result": "AC", "execution_time": "1502 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA2954BCC26BA", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta*2,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 1, "result": "WA", "execution_time": "1042 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 2, "result": "WA", "execution_time": "1345 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 3, "result": "RE", "execution_time": "1192 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ntheta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 4, "result": "RE", "execution_time": "1051 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ntheta = Parameter(\"thet\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 5, "result": "RE", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ntheta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 6, "result": "WA", "execution_time": "1315 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 7, "result": "WA", "execution_time": "1005 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 8, "result": "RE", "execution_time": "1120 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 9, "result": "WA", "execution_time": "1097 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 10, "result": "RE", "execution_time": "1446 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(0,theta)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 11, "result": "WA", "execution_time": "1472 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(2*theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 12, "result": "RE", "execution_time": "1101 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 13, "result": "RE", "execution_time": "1426 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.P(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 14, "result": "RE", "execution_time": "1140 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# theta = Parameter(\"theta\")\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ph(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 15, "result": "RE", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.u1(theta,0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 16, "result": "WA", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 17, "result": "RE", "execution_time": "1037 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ph(theta,0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 18, "result": "WA", "execution_time": "1419 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta,0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 19, "result": "WA", "execution_time": "1147 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta,0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 20, "result": "WA", "execution_time": "1429 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(-theta,0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 21, "result": "WA", "execution_time": "1086 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # qc.p(-theta,0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3156EC10939", "submission_order": 22, "result": "RE", "execution_time": "1114 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(2*theta, qr[0])\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3B4E3728BEE", "submission_order": 1, "result": "WA", "execution_time": "1503 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AA3B4E3728BEE", "submission_order": 2, "result": "AC", "execution_time": "1399 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAC9ADE383C74", "submission_order": 1, "result": "RE", "execution_time": "1017 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAC9ADE383C74", "submission_order": 2, "result": "WA", "execution_time": "1132 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAC9ADE383C74", "submission_order": 3, "result": "WA", "execution_time": "1049 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2 * theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAC9ADE383C74", "submission_order": 4, "result": "AC", "execution_time": "1374 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAD7AD644DABD", "submission_order": 1, "result": "TLE", "execution_time": "2000 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAD7AD644DABD", "submission_order": 2, "result": "AC", "execution_time": "1453 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAE917F25206F", "submission_order": 1, "result": "AC", "execution_time": "1557 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAF4163B406B6", "submission_order": 1, "result": "RE", "execution_time": "1044 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(2*theta)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAF4163B406B6", "submission_order": 2, "result": "AC", "execution_time": "1424 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(2*theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAF47EFF27B63", "submission_order": 1, "result": "RE", "execution_time": "1548 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.t(theta)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAF47EFF27B63", "submission_order": 2, "result": "RE", "execution_time": "1082 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.t(theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AAF499C43F602", "submission_order": 1, "result": "AC", "execution_time": "1569 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(theta), 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB21F4AE7D2B7", "submission_order": 1, "result": "RE", "execution_time": "1042 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB21F4AE7D2B7", "submission_order": 2, "result": "RE", "execution_time": "1207 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(0, theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB21F4AE7D2B7", "submission_order": 3, "result": "WA", "execution_time": "1224 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB21F4AE7D2B7", "submission_order": 4, "result": "WA", "execution_time": "1292 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB21F4AE7D2B7", "submission_order": 5, "result": "WA", "execution_time": "1279 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB21F4AE7D2B7", "submission_order": 6, "result": "AC", "execution_time": "1623 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB68FEC1FE00C", "submission_order": 1, "result": "RE", "execution_time": "1251 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB68FEC1FE00C", "submission_order": 2, "result": "WA", "execution_time": "1085 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB68FEC1FE00C", "submission_order": 3, "result": "WA", "execution_time": "1788 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB68FEC1FE00C", "submission_order": 4, "result": "WA", "execution_time": "1123 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB68FEC1FE00C", "submission_order": 5, "result": "RE", "execution_time": "1151 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,1)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB68FEC1FE00C", "submission_order": 6, "result": "WA", "execution_time": "1195 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB68FEC1FE00C", "submission_order": 7, "result": "AC", "execution_time": "1585 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB8AE2658C17B", "submission_order": 1, "result": "WA", "execution_time": "1123 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB8AE2658C17B", "submission_order": 2, "result": "WA", "execution_time": "1640 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB8AE2658C17B", "submission_order": 3, "result": "AC", "execution_time": "1781 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AB9E5DC30F1F9", "submission_order": 1, "result": "AC", "execution_time": "1775 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABA701B5650BD", "submission_order": 1, "result": "WA", "execution_time": "1227 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(theta,0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABA701B5650BD", "submission_order": 2, "result": "WA", "execution_time": "1019 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.p(theta,0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABA701B5650BD", "submission_order": 3, "result": "WA", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(theta, 0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABA701B5650BD", "submission_order": 4, "result": "RE", "execution_time": "1364 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.u1(theta, 0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABD558311180C", "submission_order": 1, "result": "AC", "execution_time": "1904 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    lam = theta*2\n    qc.rz(lam,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABD56402E78B1", "submission_order": 1, "result": "WA", "execution_time": "1215 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABD56402E78B1", "submission_order": 2, "result": "WA", "execution_time": "1215 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABD56402E78B1", "submission_order": 3, "result": "WA", "execution_time": "1172 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta / 2 * pi, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABE41B127D60D", "submission_order": 1, "result": "AC", "execution_time": "1431 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABFAA6697321D", "submission_order": 1, "result": "RE", "execution_time": "1560 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABFAA6697321D", "submission_order": 2, "result": "WA", "execution_time": "1185 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ABFAA6697321D", "submission_order": 3, "result": "AC", "execution_time": "1919 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC35ACFBFD613", "submission_order": 1, "result": "AC", "execution_time": "1731 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.rz(-theta*2,0)\n    \n    return qc\n\n# if __name__ == \"__main__\":\n#     theta=np.pi/3\n#     qc = solve(theta)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B1", "user": "AC3FEECEB9AFC", "submission_order": 1, "result": "WA", "execution_time": "1347 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC3FEECEB9AFC", "submission_order": 2, "result": "AC", "execution_time": "1576 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 1, "result": "WA", "execution_time": "1339 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    # Apply the RZ gate to apply the phase e^(i*theta) to the state |0>\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 2, "result": "WA", "execution_time": "1129 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 3, "result": "WA", "execution_time": "1155 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta/2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 4, "result": "WA", "execution_time": "1472 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rx(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 5, "result": "WA", "execution_time": "1299 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.ry(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 6, "result": "WA", "execution_time": "1106 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 7, "result": "WA", "execution_time": "1196 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    qc.ry(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 8, "result": "WA", "execution_time": "1282 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta, 0)\n    qc.ry(theta, 0)\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 9, "result": "RE", "execution_time": "1163 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply a phase shift by θ using the U1 gate, which is equivalent to the RZ gate.\n    qc.u1(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 10, "result": "WA", "execution_time": "1290 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply a phase shift by θ using the U1 gate, which is equivalent to the RZ gate.\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 11, "result": "WA", "execution_time": "1091 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC586D80CFE4E", "submission_order": 12, "result": "WA", "execution_time": "1146 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC94F88904568", "submission_order": 1, "result": "WA", "execution_time": "2053 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta/2, 0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC94F88904568", "submission_order": 2, "result": "AC", "execution_time": "2467 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 1, "result": "WA", "execution_time": "1228 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 2, "result": "WA", "execution_time": "1203 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(theta, 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 3, "result": "WA", "execution_time": "1154 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(theta, 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 4, "result": "WA", "execution_time": "1447 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 5, "result": "WA", "execution_time": "1407 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 6, "result": "WA", "execution_time": "1521 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(2*theta, 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 7, "result": "WA", "execution_time": "1369 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(-2*theta, 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 8, "result": "WA", "execution_time": "1078 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(2*theta, 0)\n    qc.rz(2*theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 9, "result": "WA", "execution_time": "1059 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(2*theta, 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 10, "result": "WA", "execution_time": "1129 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.ry(2*theta, 0)\n    qc.h(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 11, "result": "WA", "execution_time": "1057 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.ry(2*theta, 0)\n    qc.h(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 12, "result": "WA", "execution_time": "1128 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-2*theta, 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 13, "result": "WA", "execution_time": "1100 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(-theta, 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 14, "result": "WA", "execution_time": "1137 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.ry(theta, 0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC98E167AD8FE", "submission_order": 15, "result": "AC", "execution_time": "1809 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = theta\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 1, "result": "RE", "execution_time": "1034 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qx.z(0)\n    qc.rx(theta, 0)\n    qx.z(0)\n    qc.rx(2 * PI - theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 2, "result": "RE", "execution_time": "1032 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qx.z(0)\n    qc.rx(theta, 0)\n    qx.z(0)\n    qc.rx(2 * 3.141592653589793 - theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 3, "result": "RE", "execution_time": "1509 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qx.z(0)\n    qc.rx(theta, 0)\n    qx.z(0)\n    qc.rx(2 * math.pi - theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 4, "result": "WA", "execution_time": "1293 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.z(0)\n    qc.rx(theta, 0)\n    qc.z(0)\n    qc.rx(2 * math.pi - theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 5, "result": "WA", "execution_time": "1028 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n    qc.x(0)\n    qc.rz(2 * math.pi - theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 6, "result": "WA", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(2 * math.pi - theta, 0)\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 7, "result": "WA", "execution_time": "1030 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta - 2 * math.pi, 0)\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 8, "result": "WA", "execution_time": "1467 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-theta + 2 * math.pi, 0)\n    qc.x(0)\n    qc.rz(-theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 9, "result": "WA", "execution_time": "1433 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz( 2 * math.pi-theta + 2 * math.pi, 0)\n    qc.x(0)\n    qc.rz( 2 * math.pi-theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 10, "result": "WA", "execution_time": "1093 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(( 2 * math.pi-theta + 2 * math.pi)*2, 0)\n    qc.x(0)\n    qc.rz( (2 * math.pi-theta)*2, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 11, "result": "WA", "execution_time": "1254 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n    qc.x(0)\n    qc.rz(math.pi - theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 12, "result": "WA", "execution_time": "1183 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n    qc.x(0)\n    qc.rz(2*math.pi - theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 13, "result": "WA", "execution_time": "1131 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-theta, 0)\n    qc.x(0)\n    #qc.rz(2*math.pi - theta, 0)\n    #qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 14, "result": "WA", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-2*math.pi + theta, 0)\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 15, "result": "WA", "execution_time": "1059 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(theta, 0)\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AC9C20123159F", "submission_order": 16, "result": "AC", "execution_time": "1727 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-theta, 0)\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA13EDF6847E", "submission_order": 1, "result": "AC", "execution_time": "1668 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # qc.rz(-2 * theta, 0)\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 1, "result": "WA", "execution_time": "1403 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(-2 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 2, "result": "WA", "execution_time": "1078 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(2 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 3, "result": "WA", "execution_time": "1063 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 4, "result": "WA", "execution_time": "1131 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(-2 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 5, "result": "WA", "execution_time": "1047 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(-2 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 6, "result": "WA", "execution_time": "1121 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(2 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 7, "result": "WA", "execution_time": "1345 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 8, "result": "WA", "execution_time": "1416 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 9, "result": "WA", "execution_time": "1181 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2 * theta * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 10, "result": "WA", "execution_time": "1018 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 11, "result": "WA", "execution_time": "1047 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 12, "result": "WA", "execution_time": "1173 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta * math.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACA2694D41048", "submission_order": 13, "result": "AC", "execution_time": "1836 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-2 * theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACC8E3EA0338D", "submission_order": 1, "result": "RE", "execution_time": "1492 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACC8E3EA0338D", "submission_order": 2, "result": "RE", "execution_time": "1406 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0, theta)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACC8E3EA0338D", "submission_order": 3, "result": "AC", "execution_time": "1598 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACCF7026EE55E", "submission_order": 1, "result": "RE", "execution_time": "1668 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-2 * theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACCF7026EE55E", "submission_order": 2, "result": "AC", "execution_time": "2025 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-2 * theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACE237D5C30C8", "submission_order": 1, "result": "WA", "execution_time": "1075 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACE237D5C30C8", "submission_order": 2, "result": "WA", "execution_time": "1180 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACE237D5C30C8", "submission_order": 3, "result": "WA", "execution_time": "1197 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2 * theta,0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACE237D5C30C8", "submission_order": 4, "result": "AC", "execution_time": "1389 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = theta\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACEA8CB86063F", "submission_order": 1, "result": "WA", "execution_time": "2192 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACEA8CB86063F", "submission_order": 2, "result": "AC", "execution_time": "2204 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ACFCDCD6C0184", "submission_order": 1, "result": "AC", "execution_time": "2100 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rz(-theta*2, 0)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD5F0C777B5FD", "submission_order": 1, "result": "AC", "execution_time": "2059 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.x(0)\n    qc.p(qubit=0, theta=theta)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD6B98D8228D5", "submission_order": 1, "result": "AC", "execution_time": "1462 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD6EBDA7B384B", "submission_order": 1, "result": "RE", "execution_time": "1259 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD6EBDA7B384B", "submission_order": 2, "result": "RE", "execution_time": "1375 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD6EBDA7B384B", "submission_order": 3, "result": "AC", "execution_time": "1735 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 1, "result": "RE", "execution_time": "1479 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta)\n    qc.rz(theta)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 2, "result": "RE", "execution_time": "1048 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    if theta != 0:\n        qc.ry(theta)\n        qc.rz(theta)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 3, "result": "RE", "execution_time": "1113 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 4, "result": "RE", "execution_time": "1146 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 5, "result": "WA", "execution_time": "1087 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    qc.rz(theta, 0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 6, "result": "WA", "execution_time": "1284 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    qc.rx(theta, 0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 7, "result": "WA", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    qc.rx(math.pi, 0)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 8, "result": "WA", "execution_time": "1097 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AD97FC6D9938A", "submission_order": 9, "result": "AC", "execution_time": "1395 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(2*theta, 0)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ADE6EC1DADB0E", "submission_order": 1, "result": "RE", "execution_time": "2190 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0, theta)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ADE6EC1DADB0E", "submission_order": 2, "result": "RE", "execution_time": "2151 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0, theta)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ADE6EC1DADB0E", "submission_order": 3, "result": "AC", "execution_time": "2341 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "ADFEF49F57D6E", "submission_order": 1, "result": "AC", "execution_time": "1692 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.u(0, 0, theta, 0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE0455A67439B", "submission_order": 1, "result": "RE", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rx(-2*theta)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE0455A67439B", "submission_order": 2, "result": "RE", "execution_time": "1349 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rx(-2*thet, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE0455A67439B", "submission_order": 3, "result": "WA", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rx(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE0455A67439B", "submission_order": 4, "result": "RE", "execution_time": "1406 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.p(theta)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE0455A67439B", "submission_order": 5, "result": "AC", "execution_time": "1433 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE1C774B0CD76", "submission_order": 1, "result": "AC", "execution_time": "1401 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE36FF620B89E", "submission_order": 1, "result": "WA", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE36FF620B89E", "submission_order": 2, "result": "WA", "execution_time": "1393 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE36FF620B89E", "submission_order": 3, "result": "RE", "execution_time": "1021 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(2*theta, 0)\n    qc.x()\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE36FF620B89E", "submission_order": 4, "result": "AC", "execution_time": "1486 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(2*theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE5238215CD00", "submission_order": 1, "result": "WA", "execution_time": "1345 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rx(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE5238215CD00", "submission_order": 2, "result": "WA", "execution_time": "1027 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE5238215CD00", "submission_order": 3, "result": "WA", "execution_time": "1267 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# generte the quantum circuit that prepares the state |ψ⟩ = cos(θ/2)|0⟩ + sin(θ/2)|1⟩\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE5238215CD00", "submission_order": 4, "result": "WA", "execution_time": "1143 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.p(theta, 0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE5238215CD00", "submission_order": 5, "result": "WA", "execution_time": "1117 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.p(theta, 0)\n    \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE5238215CD00", "submission_order": 6, "result": "AC", "execution_time": "1527 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE6725E569D98", "submission_order": 1, "result": "AC", "execution_time": "1506 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE829480A31AB", "submission_order": 1, "result": "WA", "execution_time": "1879 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Rz gate to the qubit\n    qc.rz(theta, 0)  # Apply Rz gate with angle theta to qubit 0\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 1, "result": "WA", "execution_time": "1146 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta / 2, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 2, "result": "WA", "execution_time": "1380 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 3, "result": "WA", "execution_time": "1386 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(-theta/2, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 4, "result": "WA", "execution_time": "1189 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(theta, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 5, "result": "WA", "execution_time": "1437 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(theta/2, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 6, "result": "WA", "execution_time": "1045 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta/2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 7, "result": "WA", "execution_time": "1048 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 8, "result": "WA", "execution_time": "1488 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(2*theta, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 9, "result": "WA", "execution_time": "1101 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(theta, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 10, "result": "WA", "execution_time": "1422 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(theta/2, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 11, "result": "RE", "execution_time": "1008 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(PhaseGate(theta), [0])\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 12, "result": "WA", "execution_time": "1351 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 13, "result": "WA", "execution_time": "1026 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta/2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 14, "result": "WA", "execution_time": "1090 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta/2, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AE98474CB03E3", "submission_order": 15, "result": "AC", "execution_time": "1385 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AEB87D3585F20", "submission_order": 1, "result": "AC", "execution_time": "2182 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = QuantumCircuit(1, global_phase=theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AEBCCC63A2928", "submission_order": 1, "result": "WA", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AEBCCC63A2928", "submission_order": 2, "result": "AC", "execution_time": "1734 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase = theta\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AEBEF539FBF81", "submission_order": 1, "result": "RE", "execution_time": "1024 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AEBEF539FBF81", "submission_order": 2, "result": "AC", "execution_time": "1551 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AEDB23A8CEA72", "submission_order": 1, "result": "RE", "execution_time": "1133 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AEDB23A8CEA72", "submission_order": 2, "result": "AC", "execution_time": "1636 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AEECD1CF12947", "submission_order": 1, "result": "AC", "execution_time": "2507 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\n# import math\n# from qiskit.quantum_info import Statevector\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(GlobalPhaseGate(theta))\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(math.pi/2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B1", "user": "AF16F3EAD6D03", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta*2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AF4E675DD8AB0", "submission_order": 1, "result": "RE", "execution_time": "2156 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AF4E675DD8AB0", "submission_order": 2, "result": "WA", "execution_time": "1991 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AF4E675DD8AB0", "submission_order": 3, "result": "WA", "execution_time": "2489 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta/2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AF4E675DD8AB0", "submission_order": 4, "result": "WA", "execution_time": "2387 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AF4E675DD8AB0", "submission_order": 5, "result": "AC", "execution_time": "2769 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(theta*2, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AF532DFB4F726", "submission_order": 1, "result": "AC", "execution_time": "1800 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-theta * 2, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFB76B99524C0", "submission_order": 1, "result": "WA", "execution_time": "1171 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFB76B99524C0", "submission_order": 2, "result": "WA", "execution_time": "1176 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFB76B99524C0", "submission_order": 3, "result": "WA", "execution_time": "1094 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta, 0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFB76B99524C0", "submission_order": 4, "result": "AC", "execution_time": "1440 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 1, "result": "RE", "execution_time": "1212 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(theta)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 2, "result": "RE", "execution_time": "1041 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(theta * 180 / math.pi)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 3, "result": "RE", "execution_time": "1237 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta * 180 / math.p)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 4, "result": "RE", "execution_time": "1046 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta * 180 / math.pi)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 5, "result": "RE", "execution_time": "1009 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta * 180 / math.pi)\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 6, "result": "WA", "execution_time": "1535 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta *  math.pi / 180, 0) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 7, "result": "WA", "execution_time": "1101 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta *  math.pi / 180, 0) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 8, "result": "WA", "execution_time": "1049 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta *  math.pi / 180, 0) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 9, "result": "WA", "execution_time": "1028 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta *  math.pi / 180, 0) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 10, "result": "WA", "execution_time": "1017 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(theta *  math.pi / 180, 0) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 11, "result": "WA", "execution_time": "1041 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.ry(theta *  math.pi / 180, 0) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 12, "result": "WA", "execution_time": "1048 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(theta *  math.pi / 180, 0) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 13, "result": "RE", "execution_time": "1034 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.r(theta *  math.pi / 180) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFCECEBFEBCE2", "submission_order": 14, "result": "WA", "execution_time": "1221 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(theta *  np.pi / 180, 0) \n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFDB8175B16C0", "submission_order": 1, "result": "RE", "execution_time": "1869 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.append(RZGate(theta))\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFDB8175B16C0", "submission_order": 2, "result": "WA", "execution_time": "1864 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.append(RZGate(theta),[0])\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B1", "user": "AFDB8175B16C0", "submission_order": 3, "result": "AC", "execution_time": "2231 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(RZGate((-2)*theta),[0])\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A030CAE9A766A", "submission_order": 1, "result": "RE", "execution_time": "1391 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A030CAE9A766A", "submission_order": 2, "result": "AC", "execution_time": "1731 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 1, "result": "WA", "execution_time": "1377 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    for i in range(n):\n        qc.p(theta,i)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 2, "result": "RE", "execution_time": "1206 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.rx(2*theta)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 3, "result": "WA", "execution_time": "1449 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.rx(2*theta,0)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 4, "result": "WA", "execution_time": "1506 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.rx(-2*theta,0)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 5, "result": "RE", "execution_time": "1168 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.mcp(n,theta)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 6, "result": "RE", "execution_time": "1113 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.mcp(theta)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 7, "result": "RE", "execution_time": "1124 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.mcp(n,theta)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 8, "result": "RE", "execution_time": "1125 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.mcp(theta)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 9, "result": "RE", "execution_time": "1122 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.mcp(theta,range(n),n)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 10, "result": "RE", "execution_time": "1127 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.mcp(theta,range(n-1),n-1)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 11, "result": "RE", "execution_time": "1135 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.mcp(theta,tuple(range(n-1)),n-1)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 12, "result": "RE", "execution_time": "1748 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    qc.mcp(theta,list(range(n-1)),n-1)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 13, "result": "RE", "execution_time": "1123 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta,0)\n    else:\n        qc.mcp(theta,lis(range(n-1)),n-1)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0424F3C380F5", "submission_order": 14, "result": "AC", "execution_time": "1849 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta,0)\n    else:\n        qc.mcp(theta,list(range(n-1)),n-1)\n    \n    for i in range(n):\n        if L >> i & 1 == 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A042D4B9DB9DD", "submission_order": 1, "result": "RE", "execution_time": "1918 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import U1Gate\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if ~L >> i & 1:\n            qc.x(i)\n    \n    qc.append(U1Gate(theta).control(n-1), list(range(n)))\n\n    for i in range(n):\n        if ~L >> i & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A042D4B9DB9DD", "submission_order": 2, "result": "AC", "execution_time": "2054 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import U1Gate\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if ~L >> i & 1:\n            qc.x(i)\n    \n    if n == 1:\n        qc.append(U1Gate(theta), list(range(n)))\n    else:\n        qc.append(U1Gate(theta).control(n-1), list(range(n)))\n\n    for i in range(n):\n        if ~L >> i & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A049A68539C21", "submission_order": 1, "result": "AC", "execution_time": "1971 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if (L >> i & 1) == 0:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if (L >> i & 1) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A086F07FF558C", "submission_order": 1, "result": "RE", "execution_time": "1101 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # Convert L to its binary representation (little-endian)\n    L_binary = format(L, f'0{n}b')[::-1]\n    \n    # Apply X gates to qubits that should be in |0⟩ state\n    for i in range(n):\n        if L_binary[i] == '0':\n            qc.x(i)\n    \n    # Apply multi-controlled phase gate\n    qc.mcphase(theta, [i for i in range(n)])\n    \n    # Apply X gates again to restore the original state\n    for i in range(n):\n        if L_binary[i] == '0':\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A086F07FF558C", "submission_order": 2, "result": "WA", "execution_time": "1100 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Convert L to binary and get its bit representation\n    # Note: The default little-endian encoding will work directly with bin(L)[2:]\n    binary_L = bin(L)[2:].zfill(n)\n    \n    # Create a list to store the qubits involved in the phase gate\n    phase_qubits = []\n    \n    for i, bit in enumerate(reversed(binary_L)):\n        if bit == '1':\n            phase_qubits.append(i)\n    \n    # Apply the phase gate to the target qubits\n    if phase_qubits:\n        qc.p(theta, phase_qubits[0])\n        for i in range(1, len(phase_qubits)):\n            qc.cp(theta, phase_qubits[i], phase_qubits[0])\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A086F07FF558C", "submission_order": 3, "result": "WA", "execution_time": "1099 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Convert L to its binary representation\n    L_bin = [int(b) for b in format(L, f'0{n}b')]\n    \n    # Apply phase shift e^{iθ} to the state |L⟩\n    for qubit in range(n):\n        if L_bin[qubit] == 1:\n            qc.x(qubit)  # Flip qubit to make the controlled phase gate apply\n    \n    # Apply the phase shift to all qubits\n    qc.rz(theta, range(n))  # Apply phase shift Rz(theta) to all qubits\n    \n    # Flip qubits back to their original state\n    for qubit in range(n):\n        if L_bin[qubit] == 1:\n            qc.x(qubit)  # Flip qubit back\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0A0A5D41C058", "submission_order": 1, "result": "RE", "execution_time": "1512 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    ii = [i for i in range(n) if (L >> i) & 1 == 0]\n\n    qc.x(ii)\n    qc.mcp(theta, list(range(1, n)), 0)\n    qc.x(ii)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0A0A5D41C058", "submission_order": 2, "result": "RE", "execution_time": "2166 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    ii = [i for i in range(n) if (L >> i) & 1 == 0]\n\n    ii and qc.x(ii)\n    qc.mcp(theta, list(range(1, n)), 0)\n    ii and qc.x(ii)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0A0A5D41C058", "submission_order": 3, "result": "AC", "execution_time": "2485 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    ii = [i for i in range(n) if (L >> i) & 1 == 0]\n\n    ii and qc.x(ii)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(1, n)), 0)\n    ii and qc.x(ii)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 1, "result": "WA", "execution_time": "1119 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(n)[2:]\n    i=0\n    for bit in binary:\n        if bit==\"1\":\n            qc.x(i)\n        i=i+1\n    qc.rz(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 2, "result": "RE", "execution_time": "1241 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(n)[2:]\n    i=0\n    for bit in binary:\n        if bit==\"1\":\n            qc.x(i)\n        i=i+1\n    if n>1:\n        qc.rz(theta, 0).control(len(binary)-1)\n    else:\n        qc.rz(theta, 0)\n\n    i=0\n    for bit in binary:\n        if bit==\"1\":\n            qc.x(i)\n        i=i+1\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 3, "result": "RE", "execution_time": "1430 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(n)[2:]\n    i=0\n    for bit in binary:\n        if bit==\"1\":\n            qc.x(i)\n        i=i+1\n\n    qcz = QuantumCircuit(1)\n    qcz.rz(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(len(binary)-1)\n    qc.append(qcz, list(range(n)))\n\n    i=0\n    for bit in binary:\n        if bit==\"1\":\n            qc.x(i)\n        i=i+1\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 4, "result": "WA", "execution_time": "1420 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(L)[2:]\n    i=0\n    for bit in binary:\n        if bit==\"1\":\n            qc.x(i)\n        i=i+1\n\n    qcz = QuantumCircuit(1)\n    qcz.rz(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(n-1)\n    qc.append(qcz, list(range(n)))\n\n    i=0\n    for bit in binary:\n        if bit==\"1\":\n            qc.x(i)\n        i=i+1\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 5, "result": "WA", "execution_time": "1495 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(L)[2:]\n    i=0\n    for bit in binary:\n        if bit==\"0\":\n            qc.x(i)\n        i=i+1\n\n    qcz = QuantumCircuit(1)\n    qcz.rz(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(n-1)\n    qc.append(qcz, list(range(n)))\n\n    i=0\n    for bit in binary:\n        if bit==\"0\":\n            qc.x(i)\n        i=i+1\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 6, "result": "RE", "execution_time": "1509 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(L)[2:]\n    for bit in range(n):\n        if binary(bit)==\"1\":\n            qc.x(bit)\n\n    qcz = QuantumCircuit(1)\n    qcz.rz(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(n-1)\n    qc.append(qcz, list(range(n)))\n\n    for bit in range(n):\n        if binary(bit)==\"1\":\n            qc.x(bit)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 7, "result": "WA", "execution_time": "1224 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(L)[2:].zfill(n)\n    for bit in range(n):\n        if binary[bit]==\"1\":\n            qc.x(bit)\n\n    qcz = QuantumCircuit(1)\n    qcz.rz(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(n-1)\n    qc.append(qcz, list(range(n)))\n\n    for bit in range(n):\n        if binary[bit]==\"1\":\n            qc.x(bit)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 8, "result": "WA", "execution_time": "1438 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(L)[2:].zfill(n)\n    for bit in range(n):\n        if binary[bit]==\"0\":\n            qc.x(bit)\n\n    qcz = QuantumCircuit(1)\n    qcz.rz(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(n-1)\n    qc.append(qcz, list(range(n)))\n\n    for bit in range(n):\n        if binary[bit]==\"0\":\n            qc.x(bit)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 9, "result": "WA", "execution_time": "1648 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(L)[2:].zfill(n)\n    for bit in range(n):\n        if binary[bit]==\"1\":\n            qc.x(bit)\n\n    qcz = QuantumCircuit(1)\n    qcz.p(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(n-1)\n    qc.append(qcz, list(range(n)))\n\n    for bit in range(n):\n        if binary[bit]==\"1\":\n            qc.x(bit)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 10, "result": "WA", "execution_time": "1642 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(L)[2:].zfill(n)\n    for bit in range(n):\n        if binary[bit]==\"1\":\n            qc.x(bit)\n\n    qcz = QuantumCircuit(1)\n    qcz.p(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(n-1)\n    qc.append(qcz, list(range(n)))\n\n    for bit in range(n):\n        if binary[bit]==\"1\":\n            qc.x(bit)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C00890A5500", "submission_order": 11, "result": "WA", "execution_time": "1650 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary=bin(L)[2:].zfill(n)\n    for bit in range(n):\n        if binary[bit]==\"0\":\n            qc.x(bit)\n\n    qcz = QuantumCircuit(1)\n    qcz.p(theta, 0)\n    if n>1:\n        qcz=qcz.to_gate().control(n-1)\n    qc.append(qcz, list(range(n)))\n\n    for bit in range(n):\n        if binary[bit]==\"0\":\n            qc.x(bit)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 1, "result": "RE", "execution_time": "1121 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(QuantumRegister(n))\n    # Write your code here:\n    qc.append(PhaseGate(theta).control(n-1),QuantumRegister(n))\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.append(XGate(i))\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 2, "result": "RE", "execution_time": "1199 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\nfrom qiskit.circuit.library.standard_gates import XGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(PhaseGate(theta).control(n-1),QuantumRegister(n))\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.append(XGate(i))\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 3, "result": "RE", "execution_time": "1236 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library.standard_gates import PhaseGate\nfrom qiskit.circuit.library.standard_gates import XGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(PhaseGate(theta).control(n-1),QuantumRegister(n))\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.append(XGate(i))\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 4, "result": "RE", "execution_time": "1561 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library.standard_gates import PhaseGate\nfrom qiskit.circuit.library.standard_gates import XGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qr1 = QuantumRegister(n)\n    qc1 = QuantumCircuit(qr1)\n    # Write your code here:\n    qc1.append(PhaseGate(theta).control(n-1),qr1)\n\n    qr2 = QuantumRegister(n)\n    qc2 = QuantumCircuit(qr2)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc2.x(i)\n    \n    qc1.append(qc2.to_gate(),qr1)\n\n    return qc1\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 5, "result": "RE", "execution_time": "1476 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import MCPhaseGate\nfrom qiskit.circuit.library.standard_gates import XGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qr1 = QuantumRegister(n)\n    qc1 = QuantumCircuit(qr1)\n    # Write your code here:\n    qc1.append(MCPhaseGate(theta,n-1),qr1)\n\n    qr2 = QuantumRegister(n)\n    qc2 = QuantumCircuit(qr2)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc2.x(i)\n    \n    qc1.append(qc2.to_gate(),qr1)\n\n    return qc1\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nfrom qiskit.circuit.library.standard_gates import XGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qr1 = QuantumRegister(n)\n    qc1 = QuantumCircuit(qr1)\n    # Write your code here:\n    qc1.append(MCPhaseGate(theta,n-),qr1)\n\n    qr2 = QuantumRegister(n)\n    qc2 = QuantumCircuit(qr2)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc2.x(i)\n    \n    qc1.append(qc2.to_gate(),qr1)\n\n    return qc1\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 7, "result": "RE", "execution_time": "1468 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nfrom qiskit.circuit.library.standard_gates import XGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qr1 = QuantumRegister(n)\n    qc1 = QuantumCircuit(qr1)\n    # Write your code here:\n    qc1.append(MCPhaseGate(theta,n-1),qr1)\n\n    qr2 = QuantumRegister(n)\n    qc2 = QuantumCircuit(qr2)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc2.x(i)\n    \n    qc1.append(qc2.to_gate(),qr1)\n\n    return qc1\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 8, "result": "RE", "execution_time": "1617 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cp(theta,range(n-1),n-1)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 9, "result": "WA", "execution_time": "1094 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1:\n        qc.p(theta,0)\n        if L==0:\n            qc.x(0)\n        return qc\n    qc.cp(theta,range(n-1),n-1)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A0C910E88258B", "submission_order": 10, "result": "WA", "execution_time": "1427 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1:\n        qc.p(theta,0)\n        if L==0:\n            qc.x(0)\n        return qc\n    qc.cp(theta,control_qubit=range(n-1),target_qubit=n-1)\n    for i in range(n):\n        if (L>>i)%2==0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A1267E41202F6", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if(L =< n):\n        for i in range(n):\n            if (i = L):        \n                qc.p(theta,i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A1267E41202F6", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if(L =< n):\n        for i in range(n):\n            if (i = L):        \n                qc.p(theta,i-1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')][::-1]\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(-2*theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')][::-1]\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')][::-1]\n\n    qc.h(0)\n    qc.h(1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 9, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    qc.h(0)\n    qc.h(1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 10, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    qc.h(0)\n    qc.h(1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i,bit enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 11, "result": "RE", "execution_time": "1163 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    qc.h(0)\n    qc.h(1)\n\n    for i,bit in enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i,bit in enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 12, "result": "RE", "execution_time": "1743 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')][::-1]\n\n    qc.h(0)\n    qc.h(1)\n\n    for i,bit in enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i,bit in enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 13, "result": "RE", "execution_time": "1530 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')][::-1]\n\n    for i in range(n):\n        qc.h(i)\n\n    for i,bit in enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i,bit in enumerate(bL):\n        if bit == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13B11B508026", "submission_order": 14, "result": "RE", "execution_time": "1076 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bL = [int(b) for b in format(L, f'0{n}b')]\n\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(n):\n        if bL[i] == 1:\n            qc.cx(i, n-1)\n\n    qc.rz(2*theta, n-1)\n\n    for i in range(n):\n        if bL[i] == 1:\n            qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 1, "result": "RE", "execution_time": "1030 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n\n    mcrz = MCRZGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcrz, list(range(n)))\n\n    binary_str = bin(L)[2:]\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n      \n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n\n    mcrz = MCRZGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcrz, list(range(n)))\n\n    binary_str = bin(L)[2:]\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n      \n    \n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n\n    mcrz = MCRZGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcrz, list(range(n)))\n\n    bit_array = bin(L)[2:]\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n      \n    \n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCRZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n\n    mcrz = MCRZGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcrz, list(range(n)))\n\n    bit_array = bin(L)[2:]\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n      \n    \n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCRZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n      \n    \n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n\n      \n    \n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 7, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCRZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n    mcrz = MCRZGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcrz, list(range(n)))\n\n    bit_array = bin(L)[2:]\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 8, "result": "RE", "execution_time": "3000 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcphase, list(range(n)))\n\n    bit_array = bin(L)[2:]\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 9, "result": "RE", "execution_time": "1182 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcphase, list(range(n)))\n\n    bit_array = bin(L)[2:]\n    bit_array = list(binary_str)\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 10, "result": "RE", "execution_time": "1550 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcphase, list(range(n)))\n\n    bit_array = bin(L)[2:].zfill(n)\n    bit_array = list(binary_str)\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 11, "result": "RE", "execution_time": "1151 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcphase, list(range(n)))\n\n    bit_array = bin(L)[2:].zfill(n)\n    bit_array = list(binary_str)\n\n    for i, bit in enumerate(bit_array):\n      if bit == '0':\n        qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 12, "result": "RE", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n  mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n  qc.append(mcphase, list(range(n)))\n\n  bit_array = bin(L)[2:].zfill(n)\n  bit_array = list(binary_str)\n\n  for i, bit in enumerate(reversed(bit_array)):\n    if bit == '0':\n      qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 13, "result": "RE", "execution_time": "1930 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n  mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n  qc.append(mcphase, list(range(n)))\n\n  binary_str = bin(L)[2:].zfill(n)\n  bit_array = list(binary_str)\n\n  for i, bit in enumerate(reversed(bit_array)):\n    if bit == '0':\n      qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 14, "result": "RE", "execution_time": "2479 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n  mcphase = MCPhaseGate(theta, num_ctrl_qubits = n-1)\n  qc.append(mcphase, list(range(n)))\n\n  binary_str = bin(L)[2:].zfill(n)\n  bit_array = list(binary_str)\n\n  for i, bit in enumerate(bit_array):\n    if bit == '0':\n      qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 15, "result": "RE", "execution_time": "2657 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n  mcphase = MCPhaseGate(theta, num_ctrl_qubits = n-1)\n  qc.append(mcphase, list(range(n)))\n\n  #binary_str = bin(L)[2:].zfill(n)\n  #bit_array = list(binary_str)\n\n  #for i, bit in enumerate(reversed(bit_array)):\n  #  if bit == '0':\n  #    qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 16, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n  if(n==1):\n\n  else:\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits = n-1)\n    qc.append(mcphase, list(range(n)))\n\n    #binary_str = bin(L)[2:].zfill(n)\n    #bit_array = list(binary_str)\n\n    #for i, bit in enumerate(reversed(bit_array)):\n    #  if bit == '0':\n    #    qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 17, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n  if n == 1 :\n\n  else:\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits = n-1)\n    qc.append(mcphase, list(range(n)))\n\n    #binary_str = bin(L)[2:].zfill(n)\n    #bit_array = list(binary_str)\n\n    #for i, bit in enumerate(reversed(bit_array)):\n    #  if bit == '0':\n    #    qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 18, "result": "WA", "execution_time": "1395 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n  if n == 1 :\n    pass\n  else:\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits = n-1)\n    qc.append(mcphase, list(range(n)))\n\n    #binary_str = bin(L)[2:].zfill(n)\n    #bit_array = list(binary_str)\n\n    #for i, bit in enumerate(reversed(bit_array)):\n    #  if bit == '0':\n    #    qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 19, "result": "WA", "execution_time": "1587 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  for i in range(n):\n    qc.h(i)\n\n  if n == 1 :\n    pass\n  else:\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcphase, list(range(n)))\n\n    binary_str = bin(L)[2:].zfill(n)\n    bit_array = list(binary_str)\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 20, "result": "WA", "execution_time": "1571 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  if n == 1 :\n    pass\n  else:\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcphase, list(range(n)))\n\n    binary_str = bin(L)[2:].zfill(n)\n    bit_array = list(binary_str)\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 21, "result": "WA", "execution_time": "1955 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n  if n == 1 :\n    pass\n  else:\n    binary_str = bin(L)[2:].zfill(n)\n    bit_array = list(binary_str)\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcphase, list(range(n)))\n\n    for i, bit in enumerate(reversed(bit_array)):\n      if bit == '0':\n        qc.x(i)\n\n\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A13E9DBCB80E2", "submission_order": 22, "result": "AC", "execution_time": "1992 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  # Write your code here:\n\n  binary_str = bin(L)[2:].zfill(n)\n  bit_array = list(binary_str)\n\n  for i, bit in enumerate(reversed(bit_array)):\n    if bit == '0':\n      qc.x(i)\n\n  if n == 1 :\n    qc.rz(theta, 0)\n  else:\n    mcphase = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    qc.append(mcphase, list(range(n)))\n\n  for i, bit in enumerate(reversed(bit_array)):\n    if bit == '0':\n      qc.x(i)\n\n\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14237A626F62", "submission_order": 1, "result": "RE", "execution_time": "1610 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    L_bin = bin(L)[2:].zfill(n)\n    for i, bit in enumerate(L_bin):\n        if bit == '0':\n            qc.x(i)\n            \n    qc.append(PhaseGate(theta).control(n - 2), range(n - 1))\n    \n    for i, bit in enumerate(L_bin):\n        if bit == '0':\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14237A626F62", "submission_order": 2, "result": "RE", "execution_time": "1344 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    L_bin = bin(L)[2:].zfill(n)\n    for i, bit in enumerate(L_bin):\n        if bit == '0':\n            qc.x(i)\n            \n    qc.append(PhaseGate(theta).control(n - 1), range(n))\n    \n    for i, bit in enumerate(L_bin):\n        if bit == '0':\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14237A626F62", "submission_order": 3, "result": "RE", "execution_time": "1611 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n            \n    qc.append(PhaseGate(theta).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14237A626F62", "submission_order": 4, "result": "AC", "execution_time": "2341 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(PhaseGate(theta), [0])\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 1, "result": "RE", "execution_time": "1266 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    flipnum = 0\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            flipnum += 1\n            fliplist.append(i)\n    qc.append(PhaseGate(theta).control(flipnum), fliplist)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 2, "result": "RE", "execution_time": "1145 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    flipnum = 0\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            flipnum += 1\n            fliplist.append(i)\n    qc.append(PhaseGate(theta).control(flipnum), fliplist)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 3, "result": "RE", "execution_time": "1117 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    flipnum = 0\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            flipnum += 1\n            fliplist.append(i)\n    qc.append(PhaseGate(theta).control(flipnum), fliplist)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 4, "result": "RE", "execution_time": "1110 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            fliplist.append(i)\n    qc.append(PhaseGate(theta).control(n), range(n))\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 5, "result": "RE", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            fliplist.append(i)\n    qc.append(PhaseGate(theta).control(n), range(n)+0)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 6, "result": "RE", "execution_time": "1088 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            fliplist.append(i)\n    list = [i for i in range(n)] + [0]\n    qc.append(PhaseGate(theta).control(n), )\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 7, "result": "RE", "execution_time": "1115 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            fliplist.append(i)\n    list = [i for i in range(n)] + [0]\n    qc.append(PhaseGate(theta).control(n), list)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 8, "result": "RE", "execution_time": "1425 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            fliplist.append(i)\n    list = [i for i in range(n)] + [0]\n    qc.append(PhaseGate(theta).control(n), lis)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 9, "result": "RE", "execution_time": "1755 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            fliplist.append(i)\n    list = [i for i in range(n)] + [0]\n    qc.append(PhaseGate(theta).control(n), list)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 10, "result": "RE", "execution_time": "2223 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            fliplist.append(i)\n    list = [i for i in range(n)]\n    qc.append(PhaseGate(theta).control(n - 1), list)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14D4F3698F74", "submission_order": 11, "result": "AC", "execution_time": "2569 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    fliplist = []\n    for i in range(n):\n        if ((L>>i)&1) == 0:\n            qc.x(i)\n            fliplist.append(i)\n    list = [i for i in range(n)]\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), list)\n    for idx in fliplist:\n        qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14E0EB4CA720", "submission_order": 1, "result": "RE", "execution_time": "1141 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Convert L to a binary string with n bits\n    L_bin = format(L, f'0{n}b')\n\n    # Apply X gates to qubits where L_bin is 0 (flips the basis)\n    for i in range(n):\n        if L_bin[i] == '0':\n            qc.x(i)\n    \n    # Apply the multi-controlled phase gate\n    # We use MCPhase to apply a controlled phase shift of e^(i * theta)\n    qc.append(MCPhase(theta, num_ctrl_qubits=n-1), list(range(n)))\n\n    # Reapply X gates to revert the basis to original\n    for i in range(n):\n        if L_bin[i] == '0':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14E0EB4CA720", "submission_order": 2, "result": "RE", "execution_time": "1325 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n # Apply Hadamard to the control qubits to create superposition\n    for i in range(n - 1):\n        qc.h(i)\n    \n    # Apply multi-controlled Toffoli gate (control on all qubits except target)\n    if n > 1:\n        # Create a multi-controlled Toffoli gate\n        from qiskit.circuit.library import MCXGate\n        mct = MCXGate(n - 1)\n        \n        # Apply multi-controlled Toffoli gate\n        qc.append(mct, range(n - 1) + [target_qubit])\n    \n    # Apply a phase gate to introduce the phase of i\n    # Phase i corresponds to a RZ rotation of pi/2 and then a RY rotation of -pi/2\n    qc.rz(math.pi / 2, target_qubit)  # Phase shift by pi/2\n    qc.ry(-math.pi / 2, target_qubit) # Phase shift by -pi/2\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14E0EB4CA720", "submission_order": 3, "result": "RE", "execution_time": "1174 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # Convert L to binary and apply X gates to the target qubit to flip it if L is set\n    binary_L = [int(bit) for bit in format(L, f'0{n}b')]\n    \n    for i, bit in enumerate(binary_L):\n        if bit == 1:\n            qc.x(i)\n    \n    # Apply a multi-controlled Toffoli gate to flip the phase of the target qubit\n    if n > 1:\n        mct = MCXGate(n - 1)  # Multi-controlled Toffoli gate\n        qc.append(mct, range(n) + [n])\n    \n    # Apply a phase shift of e^{iθ} to the target qubit\n    qc.p(theta, n)  # Use phase gate to introduce the phase shift\n    \n    # Clean up: Apply X gates again to reverse the effect if necessary\n    for i, bit in enumerate(binary_L):\n        if bit == 1:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14E0EB4CA720", "submission_order": 4, "result": "RE", "execution_time": "1057 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.p(theta, L)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A14E0EB4CA720", "submission_order": 5, "result": "RE", "execution_time": "1495 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.p(theta, L)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A19F1FDC6D9A4", "submission_order": 1, "result": "RE", "execution_time": "1127 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Step 1: Apply X gates to flip the bits that are 0 in L to 1\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n    \n    # Step 2: Apply a multi-controlled Rz gate to introduce the phase e^(iθ) to the state |L⟩\n    qc.mcrz(theta, list(range(n)), 0)\n    \n    # Step 3: Apply X gates again to revert the changes made by the first set of X gates\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A19F1FDC6D9A4", "submission_order": 2, "result": "RE", "execution_time": "1190 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Step 1: Apply X gates to match the bits of L\n    for i in range(n):\n        if (L >> i) & 1 == 0:  # If the i-th bit of L is 0, apply X to qubit i\n            qc.x(i)\n    \n    # Step 2: Apply a multi-controlled Rz gate (controlled on all n qubits)\n    qc.mcrz(theta, list(range(n)), 0)\n    \n    # Step 3: Apply X gates again to revert the initial bit flips\n    for i in range(n):\n        if (L >> i) & 1 == 0:  # Revert the X gate applied earlier\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A1DD657E22D15", "submission_order": 1, "result": "RE", "execution_time": "1444 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bitstr = bin(L)[2:].zfill(n)[::-1]  # 2進数表記に変換して逆順にする\n\n    last_bit = bitstr[-1]\n    bitstr = bitstr[:-1]  # 最後のビットは制御ビットに使うので除外\n\n    if last_bit == \"1\":\n        qc.x(n - 1)\n    qc.mcp(theta, list(range(n - 1)), n - 1, ctrl_state=bitstr)\n    if last_bit == \"1\":\n        qc.x(n - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A1DD657E22D15", "submission_order": 2, "result": "WA", "execution_time": "1273 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n >= 2:\n        bitstr = bin(L)[2:].zfill(n)[::-1]  # 2進数表記に変換して逆順にする\n\n        last_bit = bitstr[-1]\n        bitstr = bitstr[:-1]  # 最後のビットは制御ビットに使うので除外\n\n        if last_bit == \"0\":\n            qc.x(n - 1)\n        qc.mcp(theta, list(range(n - 1)), n - 1, ctrl_state=bitstr)\n        if last_bit == \"0\":\n            qc.x(n - 1)\n    else:\n        if L == 0:\n            qc.x(0)\n        qc.p(theta, 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A1DD657E22D15", "submission_order": 3, "result": "WA", "execution_time": "1661 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n >= 2:\n        bitstr = bin(L)[2:].zfill(n)  # 2進数表記に変換して逆順にする\n\n        last_bit = bitstr[-1]\n        bitstr = bitstr[:-1]  # 最後のビットは制御ビットに使うので除外\n\n        if last_bit == \"1\":\n            qc.x(n - 1)\n        qc.mcp(theta, list(range(n - 1)), n - 1, ctrl_state=bitstr)\n        if last_bit == \"1\":\n            qc.x(n - 1)\n    else:\n        if L == 0:\n            qc.x(0)\n        qc.p(theta, 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A1DD657E22D15", "submission_order": 4, "result": "WA", "execution_time": "1150 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n >= 2:\n        bitstr = bin(L)[2:].zfill(n)[::-1]  # 2進数表記に変換して逆順にする\n\n        last_bit = bitstr[-1]\n        bitstr = bitstr[:-1]  # 最後のビットは制御ビットに使うので除外\n\n        if last_bit == \"1\":\n            qc.x(n - 1)\n        qc.mcp(theta, list(range(n - 1)), n - 1, ctrl_state=bitstr)\n        if last_bit == \"1\":\n            qc.x(n - 1)\n    else:\n        if L == 0:\n            qc.x(0)\n        qc.p(theta, 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A1DD657E22D15", "submission_order": 5, "result": "AC", "execution_time": "2715 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n >= 2:\n        full_bitstr = bin(L)[2:].zfill(n)[::-1]  # 2進数表記に変換して逆順にする\n\n        for i, b in enumerate(full_bitstr):\n            if b == \"0\":\n                qc.x(i)\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n        for i, b in enumerate(full_bitstr):\n            if b == \"0\":\n                qc.x(i)\n    else:\n        if L == 0:\n            qc.x(0)\n        qc.p(theta, 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 1, "result": "RE", "execution_time": "1166 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    \n    qc.mcp(list(range(n)), 0)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 2, "result": "RE", "execution_time": "1080 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    \n    qc.mcp(theta, list(range(n)), 0)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 3, "result": "RE", "execution_time": "1399 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    \n    qc.mcp(theta,list(range(1,n)), 0)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 4, "result": "WA", "execution_time": "1210 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    \n    #qc.mcp(theta, list(range(1,n)), 0)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 5, "result": "RE", "execution_time": "1847 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    \n    #qc.mcp(theta, list(range(1,n)), 0)\n    qc.mcp(theta, [0,1,2],3)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 6, "result": "RE", "execution_time": "2486 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    \n    #qc.mcp(theta, list(range(1,n)), 0)\n    qc.mcp(theta, [0],1)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 7, "result": "WA", "execution_time": "1839 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    \n    if n > 1:\n        qc.mcp(theta, list(range(1,n)), 0)\n    else:\n        qc.p(theta, 0)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 8, "result": "WA", "execution_time": "1482 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    if n > 1:\n        qc.mcp(theta, list(range(1,n)), 0)\n    else:\n        qc.p(theta, 0)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 9, "result": "WA", "execution_time": "1039 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    if n > 1:\n        qc.mcp(theta, list(range(1,n)), 0)\n    else:\n        qc.p(theta, 0)\n\n    for i in range(n):\n        if L & (1<<(n-1-i)) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 10, "result": "WA", "execution_time": "1139 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        qc.mcp(theta, list(range(1,n)), 0)\n    else:\n        qc.p(theta, 0)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A215AE00AB66A", "submission_order": 11, "result": "AC", "execution_time": "2244 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n            \n    if n > 1:\n        qc.mcp(theta, list(range(1,n)), 0)\n    else:\n        qc.p(theta, 0)\n\n    for i in range(n):\n        if L & (1<<i) == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2632E323BDA1", "submission_order": 1, "result": "RE", "execution_time": "1109 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0[n]b}\"]\n\n    if bits[0] == 0:\n        qc.x(0)\n\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n\n    qc.mcp(theta, list(range(1, n)), 0)\n\n    if bits[0] == 0:\n        qc.x(0)\n\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2632E323BDA1", "submission_order": 2, "result": "RE", "execution_time": "2289 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n\n    if bits[0] == 0:\n        qc.x(0)\n\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n\n    qc.mcp(theta, list(range(1, n)), 0)\n\n    if bits[0] == 0:\n        qc.x(0)\n\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2632E323BDA1", "submission_order": 3, "result": "RE", "execution_time": "2205 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n\n    if bits[0] == 0:\n        qc.x(0)\n\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n\n    qc.mcp(theta, list(range(1, n)), 0)\n\n    if bits[0] == 0:\n        qc.x(0)\n\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2632E323BDA1", "submission_order": 4, "result": "RE", "execution_time": "1348 ms", "memory": "140 MiB", "code": "'''python\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n\n    if bits[0] == 0:\n        qc.x(0)\n\n    if n > 1:\n        for i, b in enumerate(bits[1:]):\n            if b == 0:\n                qc.x(i + 1)\n\n        qc.mcp(theta, list(range(1, n)), 0)\n\n        for i, b in enumerate(bits[1:]):\n            if b == 0:\n                qc.x(i + 1)\n    else:\n        qc.p(theta, 0)\n\n    if bits[0] == 0:\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2632E323BDA1", "submission_order": 5, "result": "RE", "execution_time": "1114 ms", "memory": "140 MiB", "code": "'''python\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    if bits[0] == 0:\n        qc.x(0)\n    if n > 1:\n        for i, b in enumerate(bits[1:]):\n            if b == 0:\n                qc.x(i + 1)\n        qc.mcp(theta, list(range(1, n)), 0)\n        for i, b in enumerate(bits[1:]):\n            if b == 0:\n                qc.x(i + 1)\n    else:\n        qc.p(theta, 0)\n    if bits[0] == 0:\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2632E323BDA1", "submission_order": 6, "result": "RE", "execution_time": "1140 ms", "memory": "140 MiB", "code": "'''python\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    if bits[0] == 0:\n        qc.x(0)\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n    if n > 1:\n        qc.mcp(theta, list(range(1, n)), 0)\n    else:\n        qc.p(theta, 0)\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n    if bits[0] == 0:\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2632E323BDA1", "submission_order": 7, "result": "AC", "execution_time": "2132 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = [int(x) for x in f\"{L:0{n}b}\"]\n    bits.reverse()\n    if bits[0] == 0:\n        qc.x(0)\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n    if n > 1:\n        qc.mcp(theta, list(range(1, n)), 0)\n    else:\n        qc.p(theta, 0)\n    for i, b in enumerate(bits[1:]):\n        if b == 0:\n            qc.x(i + 1)\n    if bits[0] == 0:\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A280BF3D9E187", "submission_order": 1, "result": "RE", "execution_time": "2334 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate\n\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    qc.append(PhaseGate(theta).control(n - 1), range(n))\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n\n    return qc\n\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(0.5)\n#     sv = Statevector(qc)\n#     print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n# #     sv = Statevector.from_label('+++')\n# #     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_B2", "user": "A280BF3D9E187", "submission_order": 2, "result": "RE", "execution_time": "2017 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate\n\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    if n == 1:\n        qc.append(PhaseGate(theta))\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), range(n))\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2, 1, math.pi / 2)\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     sv = Statevector.from_label('++')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_B2", "user": "A280BF3D9E187", "submission_order": 3, "result": "AC", "execution_time": "2170 ms", "memory": "161 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate\n\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    if n == 1:\n        qc.append(PhaseGate(theta), range(n))\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), range(n))\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2, 1, math.pi / 2)\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     sv = Statevector.from_label('++')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_B2", "user": "A2F055A57EF77", "submission_order": 1, "result": "RE", "execution_time": "1276 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n\n    bin_L = format(L, '0' + str(n) + 'b')  \n    \n    for i in range(n):\n        if bin_L[i] == '1':\n            qc.x(i) \n\n    qc.append(Gate(name='PHASE_SHIFT', num_qubits=n, params=[theta]), range(n))\n    \n    for i in range(n):\n        if bin_L[i] == '1':\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2F055A57EF77", "submission_order": 2, "result": "RE", "execution_time": "1048 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    bin_L = format(L, '0' + str(n) + 'b')  \n    \n    for i in range(n):\n        if bin_L[i] == '1':\n            qc.x(i) \n\n    qc.append(Gate(name='PHASE_SHIFT', num_qubits=n, params=[theta]), range(n))\n    \n    for i in range(n):\n        if bin_L[i] == '1':\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2F055A57EF77", "submission_order": 3, "result": "WA", "execution_time": "1368 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        if (L >> i) & 1:\n            qc.x(i)  \n    qc.p(theta, range(n)) \n    \n    for i in range(n):\n        if (L >> i) & 1:\n            qc.x(i)  \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2F055A57EF77", "submission_order": 4, "result": "WA", "execution_time": "1102 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        if (L >> i) & 1:\n            qc.x(i)  \n    qc.rz(theta, range(n)) \n    \n    for i in range(n):\n        if (L >> i) & 1:\n            qc.x(i)  \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2F055A57EF77", "submission_order": 5, "result": "WA", "execution_time": "1304 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        if (L >> (n-1-i)) & 1:\n            qc.x(i)  \n    qc.p(theta, range(n)) \n    \n    for i in range(n):\n        if (L >> (n-1-i)) & 1:\n            qc.x(i)  \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2F055A57EF77", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if L>>i & 0:\n            qc.x(i)\n \n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if L>>i & 0:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2F055A57EF77", "submission_order": 7, "result": "WA", "execution_time": "1499 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if L>>i & 0:\n            qc.x(i)\n \n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if L>>i & 0:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A2F055A57EF77", "submission_order": 8, "result": "AC", "execution_time": "2421 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not L>>i & 1:\n            qc.x(i)\n \n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if not L>>i & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A3A388A22AF5A", "submission_order": 1, "result": "AC", "execution_time": "2211 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (L>>i)&1:\n            qc.x(i)\n        \n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n        \n    for i in range(n):\n            if not (L>>i)&1:\n                qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4698A8A38302", "submission_order": 1, "result": "RE", "execution_time": "1139 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     # Convert L to binary and reverse it because of little-endian encoding\n    L_bin = format(L, f'0{n}b')[::-1]\n    \n    # Find the control qubits (qubits that must be in the |1> state)\n    control_qubits = [i for i in range(n) if L_bin[i] == '1']\n    \n    # Apply the multi-controlled phase shift gate\n    if control_qubits:\n        qc.mcp(theta, control_qubits, qc.qubits[0])\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4698A8A38302", "submission_order": 2, "result": "RE", "execution_time": "1560 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Convert L to binary\n    L_bin = format(L, f'0{n}b')[::-1]\n    \n    # Apply X gates to invert the necessary qubits to prepare for multi-controlled phase\n    for i in range(n):\n        if L_bin[i] == '0':\n            qc.x(i)\n    \n    # Apply multi-controlled Z gate with phase theta\n    qc.mcp(theta, list(range(1, n)), 0)  # Apply the phase with n-1 controls\n\n    # Reverse the X gates to clean up\n    for i in range(n):\n        if L_bin[i] == '0':\n            qc.x(i)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4698A8A38302", "submission_order": 3, "result": "AC", "execution_time": "2438 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #   qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if n > 1:\n\n        if ctrl_state[0] == '0':\n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.x(0)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n            qc.x(0)\n        \n        else : \n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    #qc.measure_all()\n    else :\n        if L == 0:\n            qc.x(0)\n        qc.p(theta , 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 1, "result": "WA", "execution_time": "1107 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U1Gate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 2, "result": "RE", "execution_time": "1572 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)[::-1]\n    Up = PhaseGate(theta).control(n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 3, "result": "RE", "execution_time": "1572 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)[::-1]\n    Up = PhaseGate(theta).control(n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 4, "result": "RE", "execution_time": "2023 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)[::-1]\n    Up = PhaseGate(theta).control(n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 5, "result": "RE", "execution_time": "2110 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)#[::-1]\n    Up = PhaseGate(theta).control(n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 6, "result": "RE", "execution_time": "2027 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)[::-1]\n    Up = PhaseGate(theta).control(n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 7, "result": "RE", "execution_time": "1113 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates.p import MCPhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)[::-1]\n    Up = PhaseGate(theta).control(n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 8, "result": "RE", "execution_time": "1610 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates.p import MCPhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)[::-1]\n    Up = MCPhaseGate(lam=theta, num_ctrl_qubits=n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 9, "result": "RE", "execution_time": "2143 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates.p import MCPhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)#[::-1]\n    Up = MCPhaseGate(lam=theta, num_ctrl_qubits=n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A474985106A26", "submission_order": 10, "result": "RE", "execution_time": "2017 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates.p import MCPhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n\n    bin_num = format(L,'b').zfill(n)[::-1]\n    Up = MCPhaseGate(lam=theta, num_ctrl_qubits=n-1)\n\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    qc.append(Up, [i for i in range(n)])\n    for i in range(n):\n        if bin_num[i] == '0':\n            qc.x([i])\n        else:\n            pass\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A49D9F351988C", "submission_order": 1, "result": "RE", "execution_time": "1118 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bin_L=format(L, f'0{n}b')\n    target_qubits=[i for i in range(n)]\n    for i, bit in enumerate(reversed(bin_L)):\n        if bit=='1':\n            qc.x(i)\n    qc.p(theta,0)\n    for i,bit in enumerate(reversed(bin_L)):\n        if bit=='1':\n            qc.x(I)        \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A49D9F351988C", "submission_order": 2, "result": "RE", "execution_time": "1212 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bin_L=format(L, f'0{n}b')\n    target_qubits=[i for i in range(n)]\n    for i, bit in enumerate(reversed(bin_L)):\n        if bit=='1':\n            qc.x(i)\n    qc.p(theta,[i for i in range(n)])\n    for i,bit in enumerate(reversed(bin_L)):\n        if bit=='1':\n            qc.x(I)        \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4BF13DA08575", "submission_order": 1, "result": "RE", "execution_time": "1627 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    ctls = []\n    current_index = 0\n    while L > 0:\n        if  L % 2 == 1:\n            ctls.append(current_index)\n        current_index += 1\n\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    \n    qc.mcp(theta, [i for i in range(1, n)], 0)\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4BF13DA08575", "submission_order": 2, "result": "RE", "execution_time": "2193 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    ctls = []\n    current_index = 0\n    while L > 0:\n        if  L % 2 == 1:\n            ctls.append(current_index)\n        current_index += 1\n        L/=2\n\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    \n    qc.mcp(theta, [i for i in range(1, n)], 0)\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4BF13DA08575", "submission_order": 3, "result": "RE", "execution_time": "1899 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    ctls = []\n    current_index = n-1\n    while L > 0:\n        if  L % 2 == 1:\n            ctls.append(current_index)\n        current_index -= 1\n        L/=2\n\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    \n    qc.mcp(theta, [i for i in range(1, n)], 0)\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4BF13DA08575", "submission_order": 4, "result": "RE", "execution_time": "1744 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom math import floor\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    ctls = []\n    current_index = n-1\n    while L > 0:\n        if  L % 2 == 1:\n            ctls.append(current_index)\n        current_index -= 1\n        L/=2\n        L = floor(L)\n\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    \n    qc.mcp(theta, [i for i in range(1, n)], 0)\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4BF13DA08575", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom math import floo\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    ctls = []\n    current_index = 0\n    while L > 0:\n        if  L % 2 == 1:\n            ctls.append(current_index)\n        current_index += 1\n        L/=2\n        L = floor(L)\n\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    \n    qc.mcp(theta, [i for i in range(1, n)], 0)\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4BF13DA08575", "submission_order": 6, "result": "RE", "execution_time": "2230 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom math import floor\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    ctls = []\n    current_index = 0\n    while L > 0:\n        if  L % 2 == 1:\n            ctls.append(current_index)\n        current_index += 1\n        L/=2\n        L = floor(L)\n\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    \n    qc.mcp(theta, [i for i in range(1, n)], 0)\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4BF13DA08575", "submission_order": 7, "result": "WA", "execution_time": "1632 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom math import floor\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    ctls = []\n    current_index = n-1\n    while L > 0:\n        if  L % 2 == 1:\n            ctls.append(current_index)\n        current_index -= 1\n        L/=2\n        L = floor(L)\n\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, [i for i in range(1, n)], 0)\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4BF13DA08575", "submission_order": 8, "result": "AC", "execution_time": "2054 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom math import floor\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    ctls = []\n    current_index = 0\n    while L > 0:\n        if  L % 2 == 1:\n            ctls.append(current_index)\n        current_index += 1\n        L/=2\n        L = floor(L)\n\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, [i for i in range(1, n)], 0)\n    for i in range(n):\n        if i not in ctls:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 1, "result": "RE", "execution_time": "1062 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** n)) % 2 == 0:\n            qc.x(i)\n\n    qc.x(0)\n    qc.append(PhaseGate(-2 * theta).control(3), [n - _ - 1 for _ in range(n)])\n\n    for i in range(n):\n        if (L // (2 ** n)) % 2 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 2, "result": "RE", "execution_time": "1271 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** n)) % 2 == 0:\n            qc.x(i)\n\n    qc.x(0)\n    qc.append(PhaseGate(-2 * theta).control(3), [_ for _ in range(n)])\n    qc.x(0)\n\n    for i in range(n):\n        if (L // (2 ** n)) % 2 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 3, "result": "RE", "execution_time": "1202 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n\n    qc.x(0)\n    qc.append(PhaseGate(-2 * theta).control(3), [_ for _ in range(n)])\n    qc.x(0)\n\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 4, "result": "RE", "execution_time": "1314 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n\n    qc.x(0)\n    qc.mcp(-2 * theta, [_ for _ in range(1, n)], 0)\n    qc.x(0)\n\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 5, "result": "RE", "execution_time": "1728 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(n - i - 1)\n\n    qc.x(0)\n    qc.mcp(-2 * theta, [_ for _ in range(1, n)], 0)\n    qc.x(0)\n\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 6, "result": "RE", "execution_time": "1863 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(n - i - 1)\n\n    qc.x(0)\n    qc.append(RZGate(-2 * theta).control(n - 1), [n-1-_ for _ in range(n)])\n    qc.x(0)\n\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 7, "result": "RE", "execution_time": "1948 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n\n    qc.x(0)\n    qc.append(RZGate(-2 * theta).control(n - 1), [n-1-_ for _ in range(n)])\n    qc.x(0)\n\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 8, "result": "WA", "execution_time": "1125 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n\n    qc.x(0)\n    if n > 1:\n        qc.append(RZGate(-2 * theta).control(n - 1), [n-1-_ for _ in range(n)])\n    else:\n        qc.rz(-2 * theta, 0)\n    qc.x(0)\n\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 9, "result": "RE", "execution_time": "1631 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n\n    if n > 1:\n        qc.mcp(theta, [_ for _ in range(1, n)], 0)\n    else:\n        qc.p(theta)\n\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4C6F1E0FEF82", "submission_order": 10, "result": "AC", "execution_time": "2624 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n\n    if n > 1:\n        qc.mcp(theta, [_ for _ in range(1, n)], 0)\n    else:\n        qc.p(theta, 0)\n\n    for i in range(n):\n        if (L // (2 ** i)) % 2 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 1, "result": "RE", "execution_time": "1324 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n            qc.crx(-2*theta, i, i)\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 2, "result": "RE", "execution_time": "1290 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n\n    qc.append(RZGate(-2*theta).control(n - 1), range(n))\n\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 3, "result": "RE", "execution_time": "1126 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n\n    qc.append(RZGate(-2*thet).control(n - 1), range(n))\n\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 4, "result": "RE", "execution_time": "2035 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n\n    qc.append(RZGate(-2*theta).control(n - 1), range(n))\n\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 5, "result": "WA", "execution_time": "1462 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n    if n==1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(RZGate(-2*theta).control(n - 1), range(n))\n\n    for i in range(n):\n        if (L&(1<<i))!=0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 6, "result": "WA", "execution_time": "1191 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L&(1<<i))==0:\n            qc.x(i)\n    if n==1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(RZGate(-2*theta).control(n - 1), range(n))\n\n    for i in range(n):\n        if (L&(1<<i))==0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 7, "result": "RE", "execution_time": "1438 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    if n==1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(RZGate(-2*theta).control(n - 1), range(n))\n\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 8, "result": "WA", "execution_time": "2189 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1) and n!=1:\n            qc.x(i)\n    if n==1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(RZGate(-2*theta).control(n - 1), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1) and n!=1:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 9, "result": "RE", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (1<<n)&L==0:\n            qc.x(i)\n    if n==1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(RZGate(-2*theta).control(n - 1), range(n))\n\n    for i in range(n):\n        if (1<<n)&L!=0:\n            qc.x(i)\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 10, "result": "WA", "execution_time": "1527 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (1<<n)&L==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        if (1<<n)&L!=0:\n            qc.x(i)\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 11, "result": "WA", "execution_time": "1305 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (1<<i)&L==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        if (1<<i)&L!=0:\n            qc.x(i)\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 12, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (1<<i)&L==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        if (1<<)&L==0:\n            qc.x(i)\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E1233A8A845", "submission_order": 13, "result": "AC", "execution_time": "1954 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (1<<i)&L==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        if (1<<i)&L==0:\n            qc.x(i)\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E160AF05A28", "submission_order": 1, "result": "RE", "execution_time": "2445 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n - 1, -1, -1):\n    if ((L >> i) & 1) == 0:\n      qc.x(i)\n  qc.append(PhaseGate(theta).control(n - 1), list(range(n)))\n  for i in range(n - 1, -1, -1):\n    if ((L >> i) & 1) == 0:\n      qc.x(i)\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E160AF05A28", "submission_order": 2, "result": "RE", "execution_time": "1648 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n - 1, -1, -1):\n    if ((L >> i) & 1) == 0:\n      qc.x(i)\n  if n == 1:\n    qc.append(PhaseGate(theta))\n  else:\n    qc.append(PhaseGate(theta).control(n - 1), list(range(n)))\n  for i in range(n - 1, -1, -1):\n    if ((L >> i) & 1) == 0:\n      qc.x(i)\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A4E160AF05A28", "submission_order": 3, "result": "AC", "execution_time": "2622 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n):\n    if ((L >> i) & 1) == 0:\n      qc.x(i)\n  if n == 1:\n    qc.p(theta, 0)\n  else:\n    qc.append(PhaseGate(theta).control(n - 1), list(range(n)))\n  for i in range(n):\n    if ((L >> i) & 1) == 0:\n      qc.x(i)\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A527D0B37C9FB", "submission_order": 1, "result": "RE", "execution_time": "2466 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate as PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_code = format(L, f'0{n}b')[::-1]\n    print(L_code)\n    for i in range(n):\n        if L_code[i] == \"0\":\n            qc.x(i)\n    p_gate = PGate(2*theta)\n    mc_p = p_gate.control(n - 1)\n    qc.append(mc_p, qargs=range(n))\n    for i in range(n):\n        if L_code[i] == \"0\":\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A527D0B37C9FB", "submission_order": 2, "result": "RE", "execution_time": "2248 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate as PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_code = format(L, f'0{n}b')[::-1]\n    print(L_code)\n    for i in range(n):\n        if L_code[i] == \"0\":\n            qc.x(i)\n    p_gate = PGate(theta)\n    mc_p = p_gate.control(n - 1)\n    qc.append(mc_p, qargs=range(n))\n    for i in range(n):\n        if L_code[i] == \"0\":\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A527D0B37C9FB", "submission_order": 3, "result": "AC", "execution_time": "2405 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate as PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_code = format(L, f'0{n}b')[::-1]\n    print(L_code)\n    for i in range(n):\n        if L_code[i] == \"0\":\n            qc.x(i)\n    if n >= 2:\n      p_gate = PGate(theta)\n      mc_p = p_gate.control(n - 1)\n      qc.append(mc_p, qargs=range(n))\n    else:\n      qc.p(theta, 0)\n    for i in range(n):\n        if L_code[i] == \"0\":\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A55D1D35325E8", "submission_order": 1, "result": "RE", "execution_time": "2087 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if ~L >> i & 1: qc.x(i)\n    qc.append(PhaseGate(theta).control(n - 1), range(n))\n    for i in range(n):\n        if ~L >> i & 1: qc.x(i) \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A55D1D35325E8", "submission_order": 2, "result": "AC", "execution_time": "2132 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if ~L >> i & 1: qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), range(n))\n    for i in range(n):\n        if ~L >> i & 1: qc.x(i) \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A56CDF709C935", "submission_order": 1, "result": "RE", "execution_time": "1246 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    if n > 1:\n        controls = list(range(n - 1))\n        cz_gate = ZGate().control(len(controls))\n        qc.append(cz_gate, controls + [n - 1])\n    else:\n        qc.z(0)\n\n    # Restaurar los qubits a su estado original\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A56CDF709C935", "submission_order": 2, "result": "RE", "execution_time": "1136 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    if n > 1:\n        controls = list(range(n - 1))\n        cz_gate = ZGate().control(len(controls))\n        qc.append(cz_gate, controls + [n - 1])\n    else:\n        qc.z(0)\n\n    # Restaurar los qubits a su estado original\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A56CDF709C935", "submission_order": 3, "result": "WA", "execution_time": "1379 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    \n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    # Aplicar la compuerta P controlada (Phase) al estado L\n    if n > 1:\n        controls = list(range(n - 1))\n        p_gate = PhaseGate(theta).control(len(controls))\n        qc.append(p_gate, controls + [n - 1])\n    else:\n        qc.p(theta, 0)\n\n    # Restaurar los qubits a su estado original\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A56CDF709C935", "submission_order": 4, "result": "AC", "execution_time": "2130 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    # Aplicar la compuerta P controlada (Phase) al estado L\n    if n > 1:\n        controls = list(range(n - 1))\n        p_gate = PhaseGate(theta).control(len(controls))\n        qc.append(p_gate, controls + [n - 1])\n    else:\n        qc.p(theta, 0)\n\n    # Restaurar los qubits a su estado original\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A57C5118A2C8F", "submission_order": 1, "result": "RE", "execution_time": "2237 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if not (L >> i & 1):\n            qc.x(i)\n\n    qc.cp(math.pi/2, range(n-1), n-1)\n    \n\n    for i in range(n):\n        if not (L >> i & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A57C5118A2C8F", "submission_order": 2, "result": "RE", "execution_time": "2183 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n\n    if n == 1:\n        qc.p(0)\n    else:\n        qc.mcp(math.pi/2, [range(n-1)], n-1)\n    \n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A57C5118A2C8F", "submission_order": 3, "result": "WA", "execution_time": "1866 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, [range(n-1)], n-1)\n    \n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A57C5118A2C8F", "submission_order": 4, "result": "AC", "execution_time": "2114 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    \n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A58941F81539C", "submission_order": 1, "result": "RE", "execution_time": "1399 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(L):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta)\n    else:\n        qc.append(PhaseGate(theta).control(n-1),range(n))\n    for i in range(L):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A58941F81539C", "submission_order": 2, "result": "RE", "execution_time": "2024 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta)\n    else:\n        qc.append(PhaseGate(theta).control(n-1),range(n))\n    for i in range(n):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A58941F81539C", "submission_order": 3, "result": "RE", "execution_time": "1787 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.append(PhaseGate(theta).control(n-1),range(n))\n    for i in range():\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A58941F81539C", "submission_order": 4, "result": "AC", "execution_time": "1940 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.append(PhaseGate(theta).control(n-1),range(n))\n    for i in range(n):\n        if (L>>i)&1 == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A5A8F4FC0BC33", "submission_order": 1, "result": "RE", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    list = []\n    for i in range(n):\n        if L & (1 << i):\n            list.append(i)\n    list.append(0)\n    qc.append(RZGate(theta).control(len(list)-1), list)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A5A8F4FC0BC33", "submission_order": 2, "result": "RE", "execution_time": "1494 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    list = []\n    for i in range(n):\n        if L & (1 << i):\n            list.append(i)\n    list.append(0)\n    qc.append(RZGate(theta).control(len(list)-1), list)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A5A8F4FC0BC33", "submission_order": 3, "result": "RE", "execution_time": "1434 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    l = []\n    for i in range(n):\n        if L & (1 << i):\n            l.append(i)\n    list.append(0)\n    qc.append(RZGate(theta).control(len(l)-1), l)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A5E673BA011C5", "submission_order": 1, "result": "RE", "execution_time": "1304 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            if  not((l>>i) & 1):\n                qc.x(i)\n        if n==l:\n            qc.rz(-2*theta,l)\n        for i in range(n):\n            if not ((l>>i)&1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A5FE0009A6DC7", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    l = L\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((l >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        # apply multiple controlled Phase gate\n        qc.append(PhaseGate().control(n - 1), range(n))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A5FE0009A6DC7", "submission_order": 2, "result": "WA", "execution_time": "1683 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    l = L\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((l >> i) & 1):\n            qc.x(i)\n    qc.p(theta, n - 1)\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A5FE0009A6DC7", "submission_order": 3, "result": "RE", "execution_time": "1280 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    l = L\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((l >> i) & 1):\n            qc.x(i)\n    qc.p(theta, n)\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A60811CC2D20E", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    def solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.mcp(theta, control_qubits=list(range(1, n)), target_qubit=0)\n\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A60811CC2D20E", "submission_order": 2, "result": "WA", "execution_time": "2038 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.mcp(theta, control_qubits=list(range(1, n)), target_qubit=0)\n\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A60811CC2D20E", "submission_order": 3, "result": "AC", "execution_time": "2219 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, control_qubits=list(range(1, n)), target_qubit=0)\n\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6522FD0094E1", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n    for i in range(2**n):\n      if i = L:\n        qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6522FD0094E1", "submission_order": 2, "result": "WA", "execution_time": "1300 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n    for i in range(2**n):\n      if i == L:\n        qc.rz(-2*theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6522FD0094E1", "submission_order": 3, "result": "WA", "execution_time": "1141 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n    m = 1\n    for i in range(n):\n      if (L & m) == 1:\n        qc.rz(-2*theta, i)\n    m = m << 1\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6522FD0094E1", "submission_order": 4, "result": "WA", "execution_time": "1284 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n    m = 2**(n-1)\n    for i in range(n):\n      if (L & m) == 1:\n        qc.rz(-2*theta, i)\n    m = m >> 1\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A670B9C17A322", "submission_order": 1, "result": "RE", "execution_time": "1313 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not((1 << i) & l):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta,n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n            if not((1 << i) & l):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A670B9C17A322", "submission_order": 2, "result": "RE", "execution_time": "1300 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not((1 << i) & l):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta,n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if not((1 << i) & l):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A670B9C17A322", "submission_order": 3, "result": "AC", "execution_time": "2150 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not((1 << i) & L):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta,n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if not((1 << i) & L):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A68A006F50FF7", "submission_order": 1, "result": "RE", "execution_time": "1465 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    q = 0\n    p = L % 2\n    L //= 2\n    for i in range(n-1):\n      q *= 2\n      q += L % 2\n      L //= 2\n    print(q, p)\n    if p == 0:\n      qc.x(q)\n    qc.p(theta,q)\n    if p == 0:\n      qc.x(q)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A68A006F50FF7", "submission_order": 2, "result": "RE", "execution_time": "1521 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    q = 0\n    p = L % 2\n    L //= 2\n    for i in range(n-1):\n      q *= 2\n      q += L % 2\n      L //= 2\n    if p == 0:\n      qc.x(q)\n    qc.p(theta,q)\n    if p == 0:\n      qc.x(q)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A68A006F50FF7", "submission_order": 3, "result": "RE", "execution_time": "1129 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    q = 0\n    p = L % 2\n    L //= 2\n    for i in range(n-1):\n      q *= 2\n      q += L % 2\n      L //= 2\n    print(q, p)\n    if p == 0:\n      qc.x(q)\n    qc.p(theta,q)\n    if p == 0:\n      qc.x(q)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A68A006F50FF7", "submission_order": 4, "result": "RE", "execution_time": "1753 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    q = 0\n    p = L % 2\n    L //= 2\n    for i in range(n-1):\n      q *= 2\n      q += L % 2\n      L //= 2\n    if p == 0:\n      qc.x(q)\n    qc.p(theta,q)\n    if p == 0:\n      qc.x(q)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6B0AF0E0DA00", "submission_order": 1, "result": "RE", "execution_time": "2688 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(PhaseGate(theta).control(n-1), range(n))\n    if not (L >> 0) & 1:\n        qc.x(0)\n    if not (L >> 1) & 1:\n        qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6B0AF0E0DA00", "submission_order": 2, "result": "RE", "execution_time": "1784 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(PhaseGate(theta).control(n-1), range(n))\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6B0AF0E0DA00", "submission_order": 3, "result": "RE", "execution_time": "1395 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (1 << i) & L:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, range(n-1), n-1)\n    for i in range(n):\n        if not (1 << i) & L:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6B0AF0E0DA00", "submission_order": 4, "result": "AC", "execution_time": "2159 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (1 << i) & L:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if not (1 << i) & L:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6E6634E35E78", "submission_order": 1, "result": "RE", "execution_time": "1066 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n    qc.mcp(theta,range(n))\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6E6634E35E78", "submission_order": 2, "result": "RE", "execution_time": "1338 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n    qc.mcp(theta,list(range(n)))\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6E6634E35E78", "submission_order": 3, "result": "WA", "execution_time": "1353 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n    # qc.mcp(theta,list(range(n)))\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6E6634E35E78", "submission_order": 4, "result": "RE", "execution_time": "3000 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n    qc.mcp(theta,list(range(n-1)), n-1)\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A6E6634E35E78", "submission_order": 5, "result": "AC", "execution_time": "2168 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, n-1)\n    elif n == 2:\n        qc.cp(theta, n-2, n-1)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not (L >> i & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(0)\n    else:\n        qc.append(PGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not (L >> i & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit.circuit.library import PGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not (L >> i & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(0)\n    else:\n        #qc.append(PGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not (L >> i & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 3, "result": "RE", "execution_time": "2212 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit.circuit.library import PGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not (L >> i & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(0)\n    #else:\n        #qc.append(PGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not (L >> i & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 4, "result": "RE", "execution_time": "2054 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit.circuit.library import PGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(0)\n    #else:\n        #qc.append(PGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 5, "result": "WA", "execution_time": "1688 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit.circuit.library import PGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    \n    qc.p(theta, 0)\n    #else:\n        #qc.append(PGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(PGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 7, "result": "RE", "execution_time": "1558 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(PhazeGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 8, "result": "RE", "execution_time": "1572 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(PhaseGate().control(n - 1), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 9, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CPHASEGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(CPHASEGate, range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 10, "result": "WA", "execution_time": "1685 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    qc.p(theta, 0)\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 11, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate, CPHASEGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(CPHASEGate(theta), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 12, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate, ControlledPhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(ControlledPhaseGate(theta), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A724F9CD916E1", "submission_order": 13, "result": "AC", "execution_time": "2197 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(MCPhaseGate(theta, n - 1), range(n))\n\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A727E504C6522", "submission_order": 1, "result": "WA", "execution_time": "1329 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        bit_L = list(bin(L)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n        qc.append(RZGate(- theta).control(n - 1), range(n))\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n        qc.rz(- theta, n - 1)\n    else:\n        if L % 2 == 1:\n            qc.rz(-2 * theta, n - 1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A727E504C6522", "submission_order": 2, "result": "WA", "execution_time": "1356 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        bit_L = list(bin(L)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n        qc.append(RZGate(2 * theta).control(n - 1), range(n))\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n    else:\n        if L % 2 == 1:\n            qc.rz(-2 * theta, n - 1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A727E504C6522", "submission_order": 3, "result": "WA", "execution_time": "1356 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        bit_L = list(bin(L)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n        qc.append(RZGate(- 2 * theta).control(n - 1), range(n))\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n    else:\n        if L % 2 == 1:\n            qc.rz(-2 * theta, n - 1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A727E504C6522", "submission_order": 4, "result": "WA", "execution_time": "1219 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        bit_L = list(bin(L)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n        qc.append(RZGate(-2 * theta).control(n - 1), range(n))\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n    else:\n        if L % 2 == 1:\n            qc.rz(-2 * theta, n - 1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A727E504C6522", "submission_order": 5, "result": "WA", "execution_time": "2077 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        bit_L = list(bin(L)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n    else:\n        if L % 2 == 1:\n            qc.rz(-2 * theta, n - 1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A727E504C6522", "submission_order": 6, "result": "WA", "execution_time": "2115 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        bit_L = list(bin(L)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n    else:\n        if L % 2 == 1:\n            qc.p(theta, n - 1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A727E504C6522", "submission_order": 7, "result": "AC", "execution_time": "2366 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        bit_L = list(bin(L)[2:].zfill(n))[::-1]\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n        for j, b in enumerate(bit_L):\n            if b == \"0\":\n                qc.x(j)\n    else:\n        if L == 0:\n            qc.x(0)\n        qc.p(theta, n - 1)\n        if L == 0:\n            qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A72DEB4F66A44", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCMT, PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bitstring = (f'{L:b}'.zfill(n))[::-1]\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    qc.compose(MCMT(PhaseGate(theta), num_ctrl_qubits=n - 1, num_target_qubits=1), range(n), inplace=True)\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A72DEB4F66A44", "submission_order": 2, "result": "RE", "execution_time": "2284 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.h(1)\n    # Write your code here:\n    bitstring = (f'{L:b}'.zfill(n))[::-1]\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    qc.compose(MCPhaseGate(theta, num_ctrl_qubits=n - 1), range(n), inplace=True)\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A72DEB4F66A44", "submission_order": 3, "result": "RE", "execution_time": "1900 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bitstring = (f'{L:b}'.zfill(n))[::-1]\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    qc.compose(MCPhaseGate(theta, num_ctrl_qubits=n - 1), range(n), inplace=True)\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A72DEB4F66A44", "submission_order": 4, "result": "RE", "execution_time": "2336 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bitstring = (f'{L:b}'.zfill(n))[::-1]\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    qc.compose(MCPhaseGate(theta, num_ctrl_qubits=n - 1), range(n), inplace=True)\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A72DEB4F66A44", "submission_order": 5, "result": "AC", "execution_time": "2694 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bitstring = (f'{L:b}'.zfill(n))[::-1]\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.compose(MCPhaseGate(theta, num_ctrl_qubits=n - 1), range(n), inplace=True)\n    for i, x in enumerate(bitstring):\n        if x == '0':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A72DF6548222D", "submission_order": 1, "result": "RE", "execution_time": "1888 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if ((L>>i)&1)==0:\n            qc.x(i)\n    qc.append(PhaseGate(theta).control(n-1), range(n))\n    for i in range(n):\n        if ((L>>i)&1)==0:\n            qc.x(i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3, 0, math.pi)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B2", "user": "A72DF6548222D", "submission_order": 2, "result": "AC", "execution_time": "2053 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if ((L>>i)&1)==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.append(PhaseGate(theta).control(n-1), range(n))\n    for i in range(n):\n        if ((L>>i)&1)==0:\n            qc.x(i)\n    # print(qc.depth())\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(1, 0, math.pi)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 1, "result": "RE", "execution_time": "1313 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n\n    \n    qc.mcrz(theta, list(range(n)), None)\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 2, "result": "RE", "execution_time": "1152 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    qc.mcrz(theta, list(range(n)), None)\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 3, "result": "RE", "execution_time": "1109 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    qc.mcrz(theta, list(range(n)),0)\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseOracle\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    qc.mcrz(theta, list(range(n)),None)\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseOracle\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n            qc.z(0)\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 6, "result": "RE", "execution_time": "1168 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n            qc.z(0)\n    else:\n            qc.append(ZGate().control(n - 1), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 7, "result": "WA", "execution_time": "1502 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n        qc.z(0)\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 8, "result": "RE", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n        qc.z(0)\n    else:\n        qc.append(RZGate().control(n - 1), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 9, "result": "RE", "execution_time": "1099 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n        qc.rz(theta,0)\n    else:\n        qc.append(theta,RZGate().control(n - 1), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 10, "result": "WA", "execution_time": "1397 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n        qc.rz(theta,0)\n    else:\n        qc.append(RZGate(theta).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 11, "result": "RE", "execution_time": "1442 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n        qc.rz(theta,0)\n    else:\n        qc.append(RZGate(theta).control(n), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 12, "result": "RE", "execution_time": "1283 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n        qc.rz(theta,0)\n    else:\n        qc.append(RZGate(theta).control(list(range(n))), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 13, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    for i in range(n):\n        qc.append(RZGate(theta).control(i)), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 14, "result": "RE", "execution_time": "1114 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    for i in range(n):\n        qc.append(RZGate(theta).control(i), range(n))\n    \n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 15, "result": "RE", "execution_time": "1106 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n        qc.rz(theta,0)\n    else:\n        for i in range(n):\n            qc.append(RZGate(theta).control(i), range(n))\n    \n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 16, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    if n == 1:\n        qc.rz(theta,0)\n    else:\n        qc.append(PGate(theta).control(n - 1), range(n))\n    \n    \n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 17, "result": "WA", "execution_time": "1238 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    for i in range(n):\n        qc.rz(theta,i)\n    \n    \n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 18, "result": "RE", "execution_time": "1847 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    qc.append(RZGate(theta).control(n-1), list(range(n)))\n    \n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 19, "result": "WA", "execution_time": "1254 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    for i in range(n):\n        qc.rz(theta/n,i)\n    \n    \n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 20, "result": "WA", "execution_time": "1410 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n \n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A=[]\n    for i in range(n):\n        A.append(L%2)\n        L//=2\n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    \n    for i in range(n):\n        qc.p(theta, i)\n    \n    \n\n    for i in range(n):\n        if not A[i]:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 21, "result": "WA", "execution_time": "1831 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    X=[]\n    for i in range(n):\n        X.append(L%2)\n        L//=2\n    for i in range(n):\n        if X[i]==0:\n            qc.x(i)\n    if n==1:\n        qc.rz(theta,0)\n    else:\n        z = RZGate(theta)\n        cz = z.control(n-1)\n        qc.append(cz, range(n))\n    for i in range(n):\n        if X[i]==0:\n            qc.x(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 22, "result": "RE", "execution_time": "1769 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    X=[]\n    for i in range(n):\n        X.append(L%2)\n        L//=2\n    for i in range(n):\n        if X[i]==0:\n            qc.x(i)\n    if n==1:\n        qc.rz(theta,0)\n    else:\n        assert False\n        z = RZGate(theta)\n        cz = z.control(n-1)\n        qc.append(cz, range(n))\n    for i in range(n):\n        if X[i]==0:\n            qc.x(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 23, "result": "WA", "execution_time": "2126 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    X=[]\n    for i in range(n):\n        X.append(L%2)\n        L//=2\n    for i in range(n):\n        if X[i]==1:\n            qc.x(i)\n    if n==1:\n        qc.rz(theta,0)\n    else:\n        z = RZGate(theta)\n        cz = z.control(n-1)\n        qc.append(cz, list(range(1,n))+[0])\n    for i in range(n):\n        if X[i]==1:\n            qc.x(i)\n    # Write your code here:\n\n    return qc\n\nsolve(4,2,1).draw()\n'''"}
{"problem": "QPC002_B2", "user": "A73F8FA33F36B", "submission_order": 24, "result": "AC", "execution_time": "2138 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    X=[]\n    for i in range(n):\n        X.append(L%2)\n        L//=2\n    for i in range(n):\n        if X[i]==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        p = PhaseGate(theta)\n        cp = p.control(n-1)\n        qc.append(cp, list(range(1,n))+[0])\n    for i in range(n):\n        if X[i]==0:\n            qc.x(i)\n    # Write your code here:\n\n    return qc\n\nsolve(4,2,10).draw()\n'''"}
{"problem": "QPC002_B2", "user": "A74D455A78DA8", "submission_order": 1, "result": "AC", "execution_time": "2032 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (1 << i) & L == 0:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if (1 << i) & L == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A75AAB91220A3", "submission_order": 1, "result": "WA", "execution_time": "1192 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bits = []\n    for idx in range(0, n):\n        bits.append(bool(L % 2))\n        L = L // 2\n\n    for idx in range(0, n):\n        if not bits[idx]:\n            qc.x(n - 1 - idx)\n\n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.mcp(theta, list(range(0, n - 1)), n - 1)\n\n    for idx in range(0, n):\n        if not bits[idx]:\n            qc.x(n - 1 - idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A75AAB91220A3", "submission_order": 2, "result": "AC", "execution_time": "2587 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bits = []\n    for idx in range(0, n):\n        bits.append(bool(L % 2))\n        L = L // 2\n\n    for idx in range(0, n):\n        if not bits[idx]:\n            qc.x(idx)\n\n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.mcp(theta, list(range(0, n - 1)), n - 1)\n\n    for idx in range(0, n):\n        if not bits[idx]:\n            qc.x(idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A77AE6044CE06", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standardgates import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # ステップ1: 整数Lをリトルエンディアン形式のバイナリ表現に変換\n    L_bits = []\n    temp_L = L\n    for i in range(n):\n        L_bits.append(temp_L % 2)\n        temp_L //= 2\n    \n    # ステップ2: Lのバイナリ表現で0の位置の量子ビットをXゲートで反転\n    for i in range(n):\n        if L_bits[i] == 0:\n            qc.x(i)\n    \n    # ステップ3: Multi-Controlled Phase Gateで位相θを適用\n    # すべての量子ビットが制御ビットとなる\n    control_qubits = list(range(n))\n    if n == 1:\n        qc.p(theta, 0)  # 1量子ビットの場合は通常のPhaseゲート\n    else:\n        qc.append(MCPhaseGate(theta, n-1), control_qubits)\n    \n    # ステップ4: Xゲートで反転したビットを元に戻す\n    for i in range(n):\n        if L_bits[i] == 0:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A77AE6044CE06", "submission_order": 2, "result": "WA", "execution_time": "1741 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # 整数Lをリトルエンディアン形式のバイナリ表現に変換\n    L_bits = []\n    temp_L = L\n    for i in range(n):\n        L_bits.append(temp_L % 2)\n        temp_L //= 2\n    \n    # Lのバイナリ表現で0の位置の量子ビットを反転\n    for i in range(n):\n        if L_bits[i] == 0:\n            qc.x(i)\n    \n    # n量子ビットすべてが|1⟩の時のみ位相θを適用\n    # 制御量子ビットとターゲット量子ビットを設定\n    if n == 1:\n        qc.rz(theta, 0)\n    elif n == 2:\n        qc.crz(theta, 0, 1)\n    else:\n        # 複数制御の場合は段階的に構築\n        # 最後の量子ビットをターゲットとして他すべてで制御\n        controls = list(range(n-1))\n        target = n-1\n        qc.mcx(controls, target)  # Multi-controlled X\n        qc.rz(theta, target)\n        qc.mcx(controls, target)  # 元に戻す\n    \n    # 反転したビットを元に戻す\n    for i in range(n):\n        if L_bits[i] == 0:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A77AE6044CE06", "submission_order": 3, "result": "AC", "execution_time": "2342 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # ステップ1: 整数Lをリトルエンディアン形式のバイナリ表現に変換\n    L_bits = []\n    temp_L = L\n    for i in range(n):\n        L_bits.append(temp_L % 2)\n        temp_L //= 2\n    \n    # ステップ2: Lのバイナリ表現で0の位置の量子ビットをXゲートで反転\n    for i in range(n):\n        if L_bits[i] == 0:\n            qc.x(i)\n    \n    # ステップ3: Multi-Controlled Phase Gateで位相θを適用\n    control_qubits = list(range(n))\n    if n == 1:\n        # 1量子ビットの場合はPhaseGateを直接使用\n        qc.rz(theta, 0)  # RZゲートでPhaseを実現\n    else:\n        # n≥2の場合はMCPhaseGateを使用\n        mc_phase = MCPhaseGate(theta, n-1)\n        qc.append(mc_phase, control_qubits)\n    \n    # ステップ4: Xゲートで反転したビットを元に戻す\n    for i in range(n):\n        if L_bits[i] == 0:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7B8DFED9A414", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    if n == 1\n        qc.rz(-2*theta)\n    else:\n        qc.append(RZGate().control(n-1), range(n))\n    for i in range(n):\n        if not ((l >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7B8DFED9A414", "submission_order": 2, "result": "RE", "execution_time": "1076 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta)\n    else:\n        qc.append(RZGate().control(n-1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7B8DFED9A414", "submission_order": 3, "result": "RE", "execution_time": "1035 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta)\n    else:\n        qc.append(RZGate().control(n-1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7B8DFED9A414", "submission_order": 4, "result": "RE", "execution_time": "1445 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta)\n    else:\n        qc.append(RZGate().control(n-1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7B8DFED9A414", "submission_order": 5, "result": "RE", "execution_time": "1167 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta,0)\n    else:\n        qc.append(RZGate().control(n-1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7B8DFED9A414", "submission_order": 6, "result": "WA", "execution_time": "1282 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta,0)\n    else:\n        qc.append(RZGate(-2*theta).control(n-1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7CF9B624D0B9", "submission_order": 1, "result": "WA", "execution_time": "1671 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        return qc\n    for i in range(n):\n        if (L&(1<<i)) <= 0:\n            qc.x(i)\n    qc.mcp(theta, list(range(1,n)), 0)\n    for i in range(n):\n        if (L&(1<<i)) <= 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7CF9B624D0B9", "submission_order": 2, "result": "AC", "execution_time": "2149 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        qc.x(0)\n        qc.p(theta, 0)\n        qc.x(0)\n        return qc\n    for i in range(n):\n        if (L&(1<<i)) <= 0:\n            qc.x(i)\n    qc.mcp(theta, list(range(1,n)), 0)\n    for i in range(n):\n        if (L&(1<<i)) <= 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7F83BAB4D568", "submission_order": 1, "result": "RE", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta,0)\n    else:\n        qc.append(CPhaseGate().control(theta,n - 1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7F83BAB4D568", "submission_order": 2, "result": "RE", "execution_time": "1157 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta,0)\n    else:\n        qc.append(CPhaseGate(theta).control(n - 1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7F83BAB4D568", "submission_order": 3, "result": "RE", "execution_time": "1200 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta,0)\n    else:\n        qc.append(CPhaseGate(theta=theta).control(n - 1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7F83BAB4D568", "submission_order": 4, "result": "RE", "execution_time": "1184 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta,0)\n    elif n == 2:\n        qc.cp(theta,0,1)\n    else:\n        qc.append(PhaseGate(theta=theta).control(n - 1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A7F83BAB4D568", "submission_order": 5, "result": "AC", "execution_time": "3000 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate,PhaseGate\n\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta,0)\n    elif n == 2:\n        qc.cp(theta,0,1)\n    else:\n        qc.append(PhaseGate(theta=theta).control(n - 1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A819529F5054B", "submission_order": 1, "result": "RE", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\n  for i in range(n):\n    if (L >> i) & 1 == 0:\n      qc.x(i)\n\n  qc.append(PhaseGate(theta).control(n-1), range(n))\n\n  for i in range(n):\n    if (L >> i) & 1 == 0:\n      qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A819529F5054B", "submission_order": 2, "result": "AC", "execution_time": "2360 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\n  for i in range(n):\n    if (L >> i) & 1 == 0:\n      qc.x(i)\n\n  \n  if (n > 1):\n    qc.append(PhaseGate(theta).control(n-1), range(n))\n  else:\n    qc.p(theta, 0)\n\n\n  for i in range(n):\n    if (L >> i) & 1 == 0:\n      qc.x(i)\n\n  return qc\n'''"}
{"problem": "QPC002_B2", "user": "A824DF8963CBD", "submission_order": 1, "result": "RE", "execution_time": "1283 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    binary_L = bin(L)[2:].zfill(n)\n\n    for i in range(n):\n        if binary_L[i] == '1':\n            qc.cu1(theta, i, n-1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 1, "result": "RE", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    qc.append(RZGate(theta).control(n))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 2, "result": "RE", "execution_time": "1224 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    qc.append(RZGate(theta).control(n-1))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 3, "result": "RE", "execution_time": "1120 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    qc.append(RZGate(theta).control(len(array) - 1), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 4, "result": "RE", "execution_time": "1121 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta, array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array) - 1), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 5, "result": "WA", "execution_time": "1241 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array) - 1), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 6, "result": "RE", "execution_time": "1192 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(n))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 7, "result": "WA", "execution_time": "1337 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)-1), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 8, "result": "RE", "execution_time": "1200 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(-theta).control(len(array)-1), arra)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 9, "result": "RE", "execution_time": "1472 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)-1), arra)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 10, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)-1), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(n-j-)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 11, "result": "WA", "execution_time": "1305 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)-1), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 12, "result": "RE", "execution_time": "1197 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 13, "result": "RE", "execution_time": "1216 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 14, "result": "WA", "execution_time": "1605 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)-1), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 15, "result": "WA", "execution_time": "1261 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(-j)\n    \n    if len(array) == 1:\n        qc.rz(theta,array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)-1), array)\n\n    #for j in range(n):\n    #    if L & (1 << j) == 0:\n    #        qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 16, "result": "WA", "execution_time": "1268 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta, array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)-1), array)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 17, "result": "WA", "execution_time": "1552 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n):\n        array.append(j)\n        if L & (1 << j) != 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta, array[0])\n    else:\n        qc.append(RZGate(theta).control(len(array)-1), array)\n\n    for j in range(n):\n        if L & (1 << j) != 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 18, "result": "RE", "execution_time": "1241 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if len(array) == 1:\n        qc.rz(theta, 0)\n    else:\n        qc.append(RZGate(theta).control(n-1), range(n))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 19, "result": "WA", "execution_time": "1250 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if n == 1:\n        qc.rz(theta, 0)\n    else:\n        qc.append(RZGate(theta).control(n-1), range(n))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 20, "result": "RE", "execution_time": "1170 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    #if n == 1:\n    #    qc.rz(theta, 0)\n    #else:\n    #    qc.append(RZGate(theta).control(n-1), range(n))\n    qc.GRZ(n, theta)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 21, "result": "RE", "execution_time": "1104 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    #if n == 1:\n    #    qc.rz(theta, 0)\n    #else:\n    #    qc.append(RZGate(theta).control(n-1), range(n))\n    qc.grz(n, theta)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 22, "result": "RE", "execution_time": "1316 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    #if n == 1:\n    #    qc.rz(theta, 0)\n    #else:\n    #    qc.append(RZGate(theta).control(n-1), range(n))\n    qc.grz(theta)\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 23, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate, GRZ\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    #if n == 1:\n    #    qc.rz(theta, 0)\n    #else:\n    #    qc.append(RZGate(theta).control(n-1), range(n))\n    qc.append(GRZ(n, theta))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 24, "result": "WA", "execution_time": "1173 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    if n == 1:\n        qc.rz(theta, 0)\n    else:\n        qc.append(RZGate(theta).control(n-1), range(n))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(n-j-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 25, "result": "WA", "execution_time": "1205 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if n == 1:\n        qc.rz(theta, 0)\n    else:\n        qc.append(RZGate(theta).control(n-1), range(n))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 26, "result": "WA", "execution_time": "1406 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n-1):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if n == 1:\n        qc.rz(theta, 0)\n    else:\n        qc.append(RZGate(theta).control(n-1), range(n))\n\n    for j in range(n-1):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 27, "result": "WA", "execution_time": "1035 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    array = []\n    for j in range(n-1):\n        array.append(j)\n        if L & (1 << j) == 0:\n            qc.x(j)\n    array.append(n-1)\n    \n    if n == 1:\n        qc.rz(theta, 0)\n    else:\n        qc.append(RZGate(theta).control(n-1), array)\n\n    for j in range(n-1):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 28, "result": "WA", "execution_time": "1331 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if n == 1:\n        qc.rz(theta, 0)\n    else:\n        qc.append(RZGate(theta).control(n-1), range(n))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A87672E58BB2C", "submission_order": 29, "result": "RE", "execution_time": "1449 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    if n == 1:\n        qc.rz(theta, 0)\n    else:\n        qc.append(RZGate(theta).control(n-2), range(n))\n\n    for j in range(n):\n        if L & (1 << j) == 0:\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A89D962F1F126", "submission_order": 1, "result": "RE", "execution_time": "2087 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(list(range(n)))\n    L_s = format(L, '010b')\n    bits = []\n    for i, bit in enumerate(L_s[10-n:]):\n        if bit == '0':\n            bits.append(i)\n    if bits != []:\n        qc.x(bits)\n    qc.mcp(theta, list(range(n-1)), n-1)\n    if bits != []:\n        qc.x(bits)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A89D962F1F126", "submission_order": 2, "result": "RE", "execution_time": "1627 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(list(range(n)))\n    L_s = format(L, '010b')\n    bits = []\n    for i, bit in enumerate(L_s[10-n:][::-1]):\n        if bit == '0':\n            bits.append(i)\n    if bits != []:\n        qc.x(bits)\n    qc.mcp(theta, list(range(n-1)), n-1)\n    if bits != []:\n        qc.x(bits)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A89D962F1F126", "submission_order": 3, "result": "RE", "execution_time": "2336 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_s = format(L, '010b')\n    bits = []\n    for i, bit in enumerate(L_s[10-n:][::-1]):\n        if bit == '0':\n            bits.append(i)\n    if bits != []:\n        qc.x(bits)\n    qc.mcp(theta, list(range(n-1)), n-1)\n    if bits != []:\n        qc.x(bits)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A89D962F1F126", "submission_order": 4, "result": "RE", "execution_time": "2237 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_s = format(L, '010b')\n    bits = []\n    for i, bit in enumerate(L_s[10-n:]):\n        if bit == '0':\n            bits.append(i)\n    if bits != []:\n        qc.x(bits)\n    qc.mcp(theta, list(range(n-1)), n-1)\n    if bits != []:\n        qc.x(bits)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A89D962F1F126", "submission_order": 5, "result": "RE", "execution_time": "2148 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_s = format(L, '010b')\n    bits = []\n    for i, bit in enumerate(L_s[10-n:]):\n        if bit == '0':\n            bits.append(i)\n    if bits != []:\n        qc.x(bits)\n    qc.mcp(theta, list(range(n-1)), n-1)\n    if bits != []:\n        qc.x(bits)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A89D962F1F126", "submission_order": 6, "result": "AC", "execution_time": "2346 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_s = format(L, '010b')\n    bits = []\n    for i, bit in enumerate(L_s[10-n:][::-1]):\n        if bit == '0':\n            bits.append(i)\n    if bits != []:\n        qc.x(bits)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    if bits != []:\n        qc.x(bits)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8D9101A91A3F", "submission_order": 1, "result": "WA", "execution_time": "1491 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_histogram\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import RZGate\n\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(RZGate(-2*theta).control(n-1),range(n))\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8D9101A91A3F", "submission_order": 2, "result": "WA", "execution_time": "1506 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_histogram\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import RZGate\n\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if (( L>>i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(RZGate(-2*theta).control(n-1),range(n))\n    for i in range(n):\n        if (( L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8D9101A91A3F", "submission_order": 3, "result": "WA", "execution_time": "1371 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_histogram\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import RZGate\n\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(2*theta, 0)\n    else:\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8D9101A91A3F", "submission_order": 4, "result": "WA", "execution_time": "1333 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_histogram\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import PhaseGate\n\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(PhaseGate(2*theta).control(n-1),range(n))\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8D9101A91A3F", "submission_order": 5, "result": "WA", "execution_time": "2089 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_histogram\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import PhaseGate\n\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2*theta, 0)\n    else:\n        qc.append(PhaseGate(theta).control(n-1),range(n))\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8D9101A91A3F", "submission_order": 6, "result": "WA", "execution_time": "1582 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_histogram\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import PhaseGate\n\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(2*theta, 0)\n    else:\n        qc.append(PhaseGate(2*theta).control(n-1),range(n))\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8D9101A91A3F", "submission_order": 7, "result": "AC", "execution_time": "2184 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.visualization import plot_histogram\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import PhaseGate\n\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.append(PhaseGate(theta).control(n-1),range(n))\n    for i in range(n):\n        if not (( L>>i) & 1):\n            qc.x(i)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(4,1,2)\n    print(qc.draw())\n    print(qc.depth())\n    # state = Statevector(qc)\n    # plot_histogram(state)\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 1, "result": "RE", "execution_time": "1127 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n    qc.append(ZGate(2*theta).control(n-1),range(n))        \n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 2, "result": "RE", "execution_time": "1341 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n    qc.append(ZGate(2*theta).control(n-1),range(n))        \n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 3, "result": "RE", "execution_time": "1178 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n    qc.append(RZGate(2*theta).control(n-1),range(n))        \n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 4, "result": "WA", "execution_time": "1233 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)     \n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 5, "result": "RE", "execution_time": "2690 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n    qc.append(RZGate(2*theta).control(n-1),range(n))   \n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 6, "result": "RE", "execution_time": "1748 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n    qc.append(RZGate(2*theta).control(2),[0,1,2])   \n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 7, "result": "RE", "execution_time": "1340 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 0:\n            qc.x(i)\n    qc.append(RZGate(2*theta).control(n-1),range(n))   \n    for i in range(n):\n        if L >> i == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 8, "result": "RE", "execution_time": "1349 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 0:\n            qc.x(i)\n    qc.append(RZGate(2*theta).control(n-1),range(n))   \n    for i in range(n):\n        if L >> i == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 9, "result": "RE", "execution_time": "1435 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1):\n        if L >> i == 0:\n            qc.x(i)\n    qc.x(n)\n    qc.append(RZGate(2*theta).control(n-1),range(n))\n    qc.x(n)\n    for i in range(n-1):\n        if L >> i == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 10, "result": "RE", "execution_time": "2800 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1):\n        if L >> i == 0:\n            qc.x(i)\n    qc.x(n-1)\n    qc.append(RZGate(2*theta).control(n-1),range(n))\n    qc.x(n-1)\n    for i in range(n-1):\n        if L >> i == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 11, "result": "RE", "execution_time": "2014 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if L >> i == 0:\n            qc.x(i)\n    qc.x(n-1)\n    qc.append(RZGate(2*theta).control(n-1),range(n))\n    qc.x(n-1)\n    for i in range(n):\n        if L >> i == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 12, "result": "RE", "execution_time": "1445 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.rz(2*theta)\n        qc.x(0)\n    else:\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n        qc.x(n-1)\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n        qc.x(n-1)\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 13, "result": "WA", "execution_time": "1365 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        qc.x(0)\n        qc.rz(2*theta,0)\n        qc.x(0)\n    else:\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n        qc.x(n-1)\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n        qc.x(n-1)\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 14, "result": "WA", "execution_time": "1810 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n        qc.x(n-1)\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n        qc.x(n-1)\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 15, "result": "WA", "execution_time": "1208 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 1:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n        qc.x(n-1)\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n        qc.x(n-1)\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 16, "result": "WA", "execution_time": "1194 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n        qc.x(n-1)\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n        qc.x(n-1)\n        for i in range(n):\n            if L >> i == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 17, "result": "WA", "execution_time": "1022 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        for i in range(n-1):\n            if (L >> i) & 1 == 0:\n                qc.x(i)\n        qc.x(n-1)\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n        qc.x(n-1)\n        for i in range(n-1):\n            if (L >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 18, "result": "WA", "execution_time": "1400 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        for i in range(n):\n            if (L >> i) & 1 == 0:\n                qc.x(i)\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n        for i in range(n):\n            if (L >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 19, "result": "RE", "execution_time": "1075 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        exit()\n        for i in range(n):\n            if (L >> i) & 1 == 0:\n                qc.x(i)\n\n        qc.append(RZGate(2*theta).control(n-1),range(n))\n        for i in range(n):\n            if (L >> i) & 1 == 0:\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 20, "result": "RE", "execution_time": "1208 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((L >> i) & 1):\n                qc.x(i)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(RZGate(2*theta).control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 21, "result": "RE", "execution_time": "1358 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n        qc.append(RZGate(2*theta).control(n-1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 22, "result": "WA", "execution_time": "1303 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.rz(2*theta,0)\n            qc.x(0)\n        else:\n            qc.rz(2*theta,0)\n    else:\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n        qc.append(RZGate(2*theta).control(n-1), range(n))\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 23, "result": "RE", "execution_time": "2045 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.PhaseGate(2*theta,0)\n            qc.x(0)\n        else:\n            qc.PhaseGate(2*theta,0)\n    else:\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n        qc.append(PhaseGate(2*theta).control(n-1), range(n))\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 24, "result": "RE", "execution_time": "2102 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.PhaseGate(2*theta)\n            qc.x(0)\n        else:\n            qc.PhaseGate(2*theta)\n    else:\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n        qc.append(PhaseGate(2*theta).control(n-1), range(n))\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A8E46C3DB651A", "submission_order": 25, "result": "AC", "execution_time": "2326 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if n == 1:\n        if L == 0:\n            qc.x(0)\n            qc.append(PhaseGate(theta),[0])\n            qc.x(0)\n        else:\n           qc.append(PhaseGate(theta),[0])\n    else:\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n        qc.append(PhaseGate(theta).control(n-1), range(n))\n        for i in range(n):\n            if not ((L >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 1, "result": "RE", "execution_time": "1385 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L >> i) & 1:\n            qc.cp(theta, i, n-1)\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 2, "result": "RE", "execution_time": "1139 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L >> i) & 1:\n            for j in range(n-1):\n                qc.cx(i, n-1)\n            qc.p(theta, n-1)\n            for j in range(n-1):\n                qc.cx(i, n-1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 3, "result": "RE", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Convert L to its binary representation\n    L_binary = bin(L)[2:].zfill(n)\n    \n    # Apply phase shift to the specific state |L>\n    # Create the controlled phase shift operation for |L>\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)  # Apply X gate to qubit i if the bit is 1\n    \n    # Apply the phase shift operation\n    qc.u1(theta, 0)  # Apply the phase shift to the |L> state\n    \n    # Uncompute the qubits to get back to the original state\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)  # Apply X gate to undo the earlier X gate if the bit was 1\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import X, Z, RZ\nimport numpy as np\n\ndef oracle(n: int, L: int, theta: float) -> QuantumCircuit:\n    q = QuantumRegister(n, name='q')  # Quantum register for the computational basis states\n    ancilla = QuantumRegister(1, name='ancilla')  # Ancilla qubit for phase application\n    qc = QuantumCircuit(q, ancilla)\n    \n    # Initialize ancilla qubit in |1> state\n    qc.x(ancilla)\n    \n    # Apply controlled-Z gates to check if the state equals L\n    for i in range(n):\n        if (L >> i) & 1:\n            qc.cx(q[i], ancilla)  # Apply CX gate (controlled-X) to flip ancilla qubit\n    \n    # Apply RZ gate based on ancilla qubit\n    qc.append(RZ(theta, ancilla), [ancilla])\n    \n    # Apply controlled-X gates to return ancilla qubit to |0> state\n    for i in range(n):\n        if (L >> i) & 1:\n            qc.cx(q[i], ancilla)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 5, "result": "WA", "execution_time": "1299 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Convert L to binary representation and apply the RZ gate conditionally\n    L_bin = [int(bit) for bit in format(L, f'0{n}b')]  # Convert L to a binary string\n    \n    for i in range(n):\n        if L_bin[i] == 1:\n            qc.rz(theta, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 6, "result": "WA", "execution_time": "1169 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply phase shift to the state if it matches L\n    for i in range(n):\n        if (L >> i) & 1:  # Check if the i-th bit of L is 1\n            qc.rz(theta, i)  # Apply RZ gate with angle theta to the i-th qubit\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 7, "result": "WA", "execution_time": "1263 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply phase shift to the state if it matches L\n    for i in range(n):\n        if (L >> i) & 1:  # Check if the i-th bit of L is 1\n            qc.rz(-2 * theta, i)  # Apply RZ gate with angle theta to the i-th qubit\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 8, "result": "QLE", "execution_time": "1095 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)  # Add an auxiliary qubit\n    \n    # Initialize auxiliary qubit in state |1>\n    qc.x(n)  # The auxiliary qubit is at index n\n    \n    # Apply controlled-X gates to check if the state equals L\n    for i in range(n):\n        if (L >> i) & 1:  # If the i-th bit of L is 1\n            qc.cx(i, n)  # Apply controlled-X gate\n    \n    # Apply RZ gate to the auxiliary qubit\n    qc.rz(theta, n)  # Apply the RZ gate with angle theta\n    \n    # Reverse the controlled-X gates to restore the state of the auxiliary qubit\n    for i in range(n):\n        if (L >> i) & 1:  # If the i-th bit of L is 1\n            qc.cx(i, n)  # Apply controlled-X gate\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 9, "result": "WA", "execution_time": "1280 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Convert L to binary string\n    L_bin = [int(bit) for bit in format(L, f'0{n}b')]\n    \n    # Apply phase shifts based on the bits of L\n    for i in range(n):\n        if L_bin[i] == 1:\n            qc.rz(-2 * theta, i)  # Apply RZ gate with angle -2*theta to the i-th qubit\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 10, "result": "RE", "execution_time": "1315 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Create the binary representation of L\n    L_bin = format(L, f'0{n}b')  # Binary string with leading zeros\n\n    # Apply controlled phase shifts\n    for i, bit in enumerate(L_bin):\n        if bit == '1':\n            qc.cx(i, n)  # Apply controlled X gate with the auxiliary qubit (n-th qubit)\n    \n    # Apply RZ gate to the auxiliary qubit if its state is |1⟩\n    qc.rz(theta, n)  # Apply RZ gate with angle theta\n    \n    # Reverse the controlled X gates\n    for i, bit in enumerate(L_bin):\n        if bit == '1':\n            qc.cx(i, n)  # Apply controlled X gate with the auxiliary qubit (n-th qubit)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 11, "result": "WA", "execution_time": "1323 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Convert L to binary representation\n    L_bin = format(L, f'0{n}b')  # Binary string of length n\n    \n    # Apply RZ gate with -2 * theta to the qubits where L has 1\n    for i, bit in enumerate(L_bin):\n        if bit == '1':\n            qc.rz(-2 * theta, i)  # Apply RZ gate with angle -2 * theta to qubit i\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A91E84184AD6A", "submission_order": 12, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit import QuantumRegister, ClassicalRegister\nfrom qiskit.circuit.library import MCPhaseGate\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    # Create a quantum circuit with n qubits\n    qc = QuantumCircuit(n)\n    \n    # Convert L to binary representation\n    L_bin = format(L, f'0{n}b')\n    \n    # Create the phase shift oracle\n    # We need to apply a controlled phase shift to target |L>\n    if L != 0:  # If L is 0, no phase shift is needed\n        # We use the fact that e^iθ = cos(θ) + i*sin(θ)\n        # We need to create a phase shift of -2*theta for |L>\n        theta = -2 * theta\n        \n        # Apply the phase shift to the qubits corresponding to L\n        for i, bit in enumerate(L_bin):\n            if bit == '1':\n                qc.h(i)  # Apply Hadamard gate\n        qc.rz(theta, list(range(n)))  # Apply RZ gate to all qubits\n        for i, bit in enumerate(L_bin):\n            if bit == '1':\n                qc.h(i)  # Apply Hadamard gate to invert back\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A95B49FA17511", "submission_order": 1, "result": "RE", "execution_time": "3000 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    \n        qc.mcp(theta, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A95B49FA17511", "submission_order": 2, "result": "AC", "execution_time": "2072 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if not (L & (1 << i)):\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A96B0E3AE623C", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n L_binary = format(L, f'0{n}b')\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    qc.rz(theta, range(n)) \n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A96B0E3AE623C", "submission_order": 2, "result": "WA", "execution_time": "1234 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L_binary = format(L, f'0{n}b')\n    \n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    \n    qc.rz(theta, 0)\n    \n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A96B0E3AE623C", "submission_order": 3, "result": "WA", "execution_time": "1472 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    L_binary = format(L, f'0{n}b')\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    qc.rz(theta, range(n))\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A9A7104FA4541", "submission_order": 1, "result": "AC", "execution_time": "2118 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      if not ((L>>i)&1):\n        qc.x(i)\n    if n == 1:\n      qc.u(0, theta, 0, 0)\n    else:\n      qc.append(UGate(0, theta, 0).control(n-1),range(n))\n    for i in range(n):\n      if not ((L>>i)&1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "A9DD2939788D1", "submission_order": 1, "result": "AC", "execution_time": "1919 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #yを|11...1>に変換すべくリトルエンディアンの順序で、0の桁にXゲートで反転させる\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, n-1)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n\n    #|11...1>をyに変換すべくリトルエンディアンの順序で、0の桁にXゲートで反転させる\n    for i in range(n):\n        if L&(1<<i) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AA252649B6B00", "submission_order": 1, "result": "RE", "execution_time": "1091 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_bits = format(L, f'0{n}b')\n    \n    # Apply X gates to match the state |L>\n    for i, bit in enumerate(L_bits):\n        if bit == '0':\n            qc.x(i)\n    \n    # Apply the multi-controlled Z gate with phase shift theta (Rz)\n    qc.mcrz(theta, control_qubits=list(range(n)), target_qubit=n-1)\n    \n    # Undo the X gates to revert the original state\n    for i, bit in enumerate(L_bits):\n        if bit == '0':\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AA252649B6B00", "submission_order": 2, "result": "RE", "execution_time": "1171 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_bits = format(L, f'0{n}b')\n    \n    # Apply X gates to match the state |L>\n    for i, bit in enumerate(L_bits):\n        if bit == '0':\n            qc.x(i)\n    \n    # Apply the multi-controlled phase gate\n    qc.append(PhaseGate(theta).control(n), range(n))\n\n    \n    \n    # Undo the X gates to revert the original state\n    for i, bit in enumerate(L_bits):\n        if bit == '0':\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AA252649B6B00", "submission_order": 3, "result": "RE", "execution_time": "2181 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_bits = format(L, f'0{n}b')\n    \n    # Apply X gates to match the state |L>\n    for i, bit in enumerate(L_bits):\n        if bit == '0':\n            qc.x(i)\n    \n    # Apply the multi-controlled phase gate\n    qc.append(PhaseGate(theta).control(n-1), range(n))\n    \n    # Undo the X gates to revert the original state\n    for i, bit in enumerate(L_bits):\n        if bit == '0':\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AA252649B6B00", "submission_order": 4, "result": "RE", "execution_time": "1152 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_bits = format(L, f'0{n}b')\n    \n    bit = L_bits[-1]\n    if bit == '0':\n        qc.x(n-1)\n    \n    # Apply the multi-controlled phase gate\n    qc.append(PhaseGate(theta).control(n-1), range(n))\n    \n    # Undo the X gates to revert the original state\n    if bit == '0':\n        qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AA252649B6B00", "submission_order": 5, "result": "RE", "execution_time": "1190 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    diag = [1]*(2**n)\n    diag[L-1] = np.cos(theta) + 1j * np.sin(theta)\n\n    state = diag / 2 ** n\n    qc.initialize(state, range(n))\n    # Apply the multi-controlled phase gate\n\n\n    return qc.decompose().decompose().decompose()\n'''"}
{"problem": "QPC002_B2", "user": "AA252649B6B00", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    diag = [np.sqrt(1/2**n)]*(2**n)\n    diag[L-1] = (np.cos(theta) + 1j * np.sin(theta)) / np.sqrt(2**n)\n\n    qc.initialize(diag, list(range(n)))\n    # Apply the multi-controlled phase gate\n\n\n    return qc.decompose().decompose().decompose(\n'''"}
{"problem": "QPC002_B2", "user": "AA252649B6B00", "submission_order": 7, "result": "RE", "execution_time": "1103 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    diag = [np.sqrt(1/2**n)]*(2**n)\n    diag[L-1] = (np.cos(theta) + 1j * np.sin(theta)) / np.sqrt(2**n)\n\n    qc.initialize(diag, list(range(n)))\n    # Apply the multi-controlled phase gate\n\n\n    return qc.decompose().decompose().decompose()\n'''"}
{"problem": "QPC002_B2", "user": "AA252649B6B00", "submission_order": 8, "result": "RE", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    diag = [np.sqrt(1/2**n)]*(2**n)\n    diag[L-1] = (np.cos(theta) + 1j * np.sin(theta)) / np.sqrt(2**n)\n    qc.initialize(diag, list(range(n)))\n\n    return qc.decompose().decompose().decompose().decompose().decompose().decompose()\n'''"}
{"problem": "QPC002_B2", "user": "AA2687BE923AA", "submission_order": 1, "result": "RE", "execution_time": "1683 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L>>i)&1):\n            qc.x(i)\n\n    qc.mcp(theta,[i for i in range(n-1)],n-1)\n    \n\n    for i in range(n):\n        if not ((L>>i)&1):\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AA2687BE923AA", "submission_order": 2, "result": "AC", "execution_time": "2622 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L>>i)&1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n        \n    else :\n        qc.mcp(theta,[i for i in range(n-1)],n-1)\n    \n\n    for i in range(n):\n        if not ((L>>i)&1):\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAA5359EA82EE", "submission_order": 1, "result": "WA", "execution_time": "1065 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.rz(-2 * theta, 0)\n    else:\n        qc.mcrz(-2 * theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAA5359EA82EE", "submission_order": 2, "result": "AC", "execution_time": "2635 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.append(PhaseGate(theta), [0])\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), range(n))\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAB0ACA244150", "submission_order": 1, "result": "RE", "execution_time": "1281 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L < 2**n:\n        qc.p(theta, L)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAE8914D0804B", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n:\n        if not (L>>i & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.append(PGate(theta).control(n-1),range(n))\n    for i in n:\n        if not (L>>i & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAE8914D0804B", "submission_order": 2, "result": "RE", "execution_time": "2232 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n:\n        if not (L>>i & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.mcp(theta,range(n-1),n-1)\n    for i in n:\n        if not (L>>i & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAE8914D0804B", "submission_order": 3, "result": "RE", "execution_time": "1509 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n:\n        if not (L>>i & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.mcp(theta,range(n-1),n-1)\n    for i in n:\n        if not (L>>i & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAE8914D0804B", "submission_order": 4, "result": "RE", "execution_time": "1552 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n:\n        if not (L>>i & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.mcp(theta,list(range(n-1)),n-1)\n    for i in n:\n        if not (L>>i & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAE8914D0804B", "submission_order": 5, "result": "RE", "execution_time": "1842 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n:\n        if not ((L>>i) & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.mcp(theta,list(range(n-1)),n-1)\n    for i in n:\n        if not ((L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAE8914D0804B", "submission_order": 6, "result": "RE", "execution_time": "1423 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in n:\n        if not ((L>>i) & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,n-1)\n    else:\n        qc.mcp(theta,list(range(n-1)),n-1)\n    for i in n:\n        if not ((L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AAE8914D0804B", "submission_order": 7, "result": "AC", "execution_time": "2869 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not ((L>>i) & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta,n-1)\n    else:\n        qc.mcp(theta,list(range(n-1)),n-1)\n    for i in range(n):\n        if not ((L>>i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB1ECB2BCB3A2", "submission_order": 1, "result": "RE", "execution_time": "1234 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bin_data = format(i, f'0{n}b')        \n    data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    qc.append(RZGate(-2*theta).control(n-1), range(n))\n\n    \n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB1ECB2BCB3A2", "submission_order": 2, "result": "RE", "execution_time": "1900 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bin_data = format(L, f'0{n}b')        \n    data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    qc.append(RZGate(-2*theta).control(n-1), range(n))\n\n    \n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB1ECB2BCB3A2", "submission_order": 3, "result": "RE", "execution_time": "2055 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bin_data = format(L, f'0{n}b')        \n    data_0_bits = [idx for idx, digit in enumerate(bin_data) if digit == '0']\n\n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    qc.append(RZGate(-2*theta).control(n-1), range(n))\n\n    \n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB1ECB2BCB3A2", "submission_order": 4, "result": "RE", "execution_time": "1167 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bin_data = format(i, f'0{n}b')        \n    data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    qc.append(RZGate(2*theta).control(n-1), range(n))\n\n    \n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB1ECB2BCB3A2", "submission_order": 5, "result": "RE", "execution_time": "1829 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bin_data = format(L, f'0{n}b')        \n    data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    qc.append(RZGate(2*theta).control(n-1), range(n))\n\n    \n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB1ECB2BCB3A2", "submission_order": 6, "result": "RE", "execution_time": "1176 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CPhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bin_data = format(L, f'0{n}b')        \n    data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    qc.append(CPhaseGate(theta).control(n-1), range(n))\n\n    \n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB1ECB2BCB3A2", "submission_order": 7, "result": "RE", "execution_time": "1846 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bin_data = format(L, f'0{n}b')        \n    data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    qc.append(PhaseGate(theta).control(n-1), range(n))\n\n    \n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB1ECB2BCB3A2", "submission_order": 8, "result": "AC", "execution_time": "2167 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bin_data = format(L, f'0{n}b')        \n    data_0_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0']\n\n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.append(PhaseGate(theta).control(n-1), range(n))\n\n    \n    if len(data_0_bits) > 0: \n        qc.x(data_0_bits)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZ\n\ndef decimalToBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToBinary(L, n)\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    \n    qc.append(RZ(-2*theta, 0), range(n)) \n    \n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n\n    return \n    \n\n  \n    \n\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZ\n\ndef decimalToBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToBinary(L, n)\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    \n    qc.append(RZ(-2*theta, 0), range(n)) \n    \n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n\n        return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 3, "result": "WA", "execution_time": "1218 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef decimalToBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToBinary(L, n)\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    \n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(-2*theta, i)\n    \n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n\n        return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef decimalToBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    qc.rz(theta, L)\n\n        return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 5, "result": "RE", "execution_time": "1281 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef decimalToBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    qc.rz(theta, L)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 6, "result": "WA", "execution_time": "1854 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n    \n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.rz(-2*theta, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 7, "result": "RE", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n\n    qc.rz(-2*theta, L)\n    \n   # for i, bit in enumerate(L_binary):\n   #     if bit == '1':\n  #          qc.rz(-2*theta, i) \n\n\n\n\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 8, "result": "RE", "execution_time": "1198 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n\n    qc.rz(theta, L)\n    \n   # for i, bit in enumerate(L_binary):\n   #     if bit == '1':\n  #          qc.rz(-2*theta, i) \n\n\n\n\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 9, "result": "RE", "execution_time": "1608 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n    theta = theta % (2 * np.pi)\n\n    qc.rz(theta, L)\n    \n   # for i, bit in enumerate(L_binary):\n   #     if bit == '1':\n  #          qc.rz(-2*theta, i) \n\n\n\n\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 10, "result": "WA", "execution_time": "1476 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n    theta = theta % (2 * np.pi)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(-2*theta, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 11, "result": "WA", "execution_time": "1298 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n    theta = theta % (2 * np.pi)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 12, "result": "WA", "execution_time": "1291 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n    theta = theta % (2 * np.pi)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 13, "result": "WA", "execution_time": "1119 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n    theta = theta % (2 * np.pi)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(-theta, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 14, "result": "WA", "execution_time": "1460 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(-2*theta, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 15, "result": "WA", "execution_time": "1350 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(-theta, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 16, "result": "WA", "execution_time": "1326 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 17, "result": "WA", "execution_time": "1138 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    L_binary = decimalToLittleEndianBinary(L, n)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(-2*theta, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB2A47776AF8C", "submission_order": 18, "result": "WA", "execution_time": "1174 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef decimalToLittleEndianBinary(n: int, length: int) -> str:\n    return bin(n)[2:].zfill(length)[::-1]  # Reverse the string for little-endian\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n    L_binary = decimalToLittleEndianBinary(L, n)\n\n    for i in range(n):\n        if L_binary[i] == '1':\n            qc.rz(-2*theta, i)\n\n    for i in range(n):\n        qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB37E38CEAA9A", "submission_order": 1, "result": "RE", "execution_time": "2047 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if ((1 << i) & L) == 0:\n            qc.x(i)\n\n    qc.crz(-2 * theta, range(n-1), n-1)\n\n    return qc\n\n\n# solve(3, 5, 0.5).draw('mpl').show()\n'''"}
{"problem": "QPC002_B2", "user": "AB37E38CEAA9A", "submission_order": 2, "result": "RE", "execution_time": "1808 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if ((1 << i) & L) == 0:\n            qc.x(i)\n\n    qc.cp(-2 * theta, range(n-1), n-1)\n\n    for i in range(n):\n        if ((1 << i) & L) == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB37E38CEAA9A", "submission_order": 3, "result": "WA", "execution_time": "1531 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n >= 2:\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n        qc.cp(-2 * theta, range(n-1), n-1)\n\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n    else:\n        if L == 1:\n            qc.rz(-2 * theta, 0)\n        else:\n            qc.x(0)\n            qc.rz(-2 * theta, 0)\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB37E38CEAA9A", "submission_order": 4, "result": "WA", "execution_time": "1410 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n >= 2:\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n        qc.cp(-2 * theta, range(n-1), n-1)\n\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n    else:\n        if L == 1:\n            qc.p(-2 * theta, 0)\n        else:\n            qc.x(0)\n            qc.p(-2 * theta, 0)\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB37E38CEAA9A", "submission_order": 5, "result": "WA", "execution_time": "1338 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n >= 2:\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n        qc.cp(theta, range(n-1), n-1)\n\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n    else:\n        if L == 1:\n            qc.p(theta, 0)\n        else:\n            qc.x(0)\n            qc.p(theta, 0)\n            qc.x(0)\n            from qiskit.circuit.library import ZGate\n            ZGate().control()\n\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB37E38CEAA9A", "submission_order": 6, "result": "WA", "execution_time": "1705 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n >= 2:\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n        qc.cp(theta, n-1, range(n-1))\n\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n    else:\n        if L == 1:\n            qc.p(theta, 0)\n        else:\n            qc.x(0)\n            qc.p(theta, 0)\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB37E38CEAA9A", "submission_order": 7, "result": "RE", "execution_time": "1060 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n >= 2:\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n        qc.cp(theta, n-1, range(n))\n\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n    else:\n        if L == 1:\n            qc.p(theta, 0)\n        else:\n            qc.x(0)\n            qc.p(theta, 0)\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB37E38CEAA9A", "submission_order": 8, "result": "RE", "execution_time": "1530 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n >= 2:\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n\n        from qiskit.circuit.library import PhaseGate\n        qc.append(PhaseGate(theta).control(n-1), range(n))\n        # qc.cp(theta, n-1, range(n))\n\n        for i in range(n):\n            if ((1 << i) & L) == 0:\n                qc.x(i)\n    else:\n        if L == 1:\n            qc.p(theta, 0)\n        else:\n            qc.x(0)\n            qc.p(theta, 0)\n            qc.x(0)\n\n    return qc\n\n\nsolve(3, 5, 0.5).draw('mpl').show()\n'''"}
{"problem": "QPC002_B2", "user": "AB387F4ED9920", "submission_order": 1, "result": "AC", "execution_time": "2529 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((L >> i) & 1):\n                qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(PhaseGate(theta).control(n - 1), range(n))\n\n    for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((L >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 1, "result": "RE", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    ctrl_state = ctrl_state + (2**n - len(ctrl_state))*'0'\n\n    qc.mcp(theta, ctrl_state = ctrl_state)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 2, "result": "RE", "execution_time": "1063 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    ctrl_state = ctrl_state + (2**n - len(ctrl_state))*'0'\n\n    qc.mcp(theta, ctrl_state = ctrl_state)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 3, "result": "RE", "execution_time": "1123 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    ctrl_state = ctrl_state + (2**n - len(ctrl_state)-1)*'0'\n\n    qc.mcp(theta, ctrl_state = ctrl_state, target_qubit = n-1)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    ctrl_state = ctrl_state + (2**n - len(ctrl_state)-)*'0'\n\n    qc.mcp(theta, control_qubits= [i for i in range(1, n)] , ctrl_state = L,target_qubit=0)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 5, "result": "RE", "execution_time": "1367 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    ctrl_state = ctrl_state + (2**n - len(ctrl_state)-1)*'0'\n\n    qc.mcp(theta, control_qubits= [i for i in range(1, n)] , ctrl_state = L,target_qubit=0)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 6, "result": "RE", "execution_time": "1251 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    ctrl_state = ctrl_state + (n - len(ctrl_state)-1)*'0'\n\n    ctrl_state[1:]\n\n    if ctrl_state[0] == 0:\n        qc.x(0)\n        qc.mcp(theta, control_qubits= [i for i in range(1, n)] , ctrl_state = ctrl_state,target_qubit=0)\n        qc.x(0)\n    \n    else : qc.mcp(theta, control_qubits= [i for i in range(1, n)] , ctrl_state = ctrl_state,target_qubit=0)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 7, "result": "RE", "execution_time": "1292 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    ctrl_state = ctrl_state + (n - len(ctrl_state)-1)*'0'\n\n    ctrl_state[1:]\n\n    if ctrl_state[0] == 0:\n        qc.x(0)\n        qc.mcp(theta, control_qubits= [i for i in range(1, n)] , ctrl_state = ctrl_state,target_qubit=0)\n        qc.x(0)\n    \n    else : qc.mcp(theta, control_qubits= [i for i in range(1, n)] , ctrl_state = ctrl_state,target_qubit=0)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 8, "result": "RE", "execution_time": "2202 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = (n - len(ctrl_state))*'0' + ctrl_state\n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if ctrl_state[0] == '0':\n        ctrl_state = ctrl_state[1:]\n        print(ctrl_state)\n        qc.x(0)\n        qc.mcp(theta, control_qubits= [i for i in range(1, n)] , ctrl_state = ctrl_state,target_qubit=0)\n        qc.x(0)\n    \n    else : \n        ctrl_state = ctrl_state[1:]\n        qc.mcp(theta, control_qubits= [i for i in range(1, n)] , ctrl_state = ctrl_state,target_qubit=0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 9, "result": "RE", "execution_time": "1140 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if ctrl_state[0] == '0':\n        ctrl_state = ctrl_state[-1:0:-1]\n        print(ctrl_state)\n        qc.x(0)\n        qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n        qc.x(0)\n    \n    else : \n        ctrl_state = ctrl_state[-1:0:-1]\n        print(ctrl_state)\n        qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 10, "result": "RE", "execution_time": "2218 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if ctrl_state[0] == '0':\n        ctrl_state = ctrl_state[-1:0:-1]\n        print(ctrl_state)\n        qc.x(0)\n        qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n        qc.x(0)\n    \n    else : \n        ctrl_state = ctrl_state[-1:0:-1]\n        print(ctrl_state)\n        qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    #qc.measure_all()\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 11, "result": "RE", "execution_time": "2035 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #   qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if ctrl_state[0] == '0':\n        ctrl_state = ctrl_state[-1:0:-1]\n        print(ctrl_state)\n        qc.x(0)\n        qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n        qc.x(0)\n    \n    else : \n        ctrl_state = ctrl_state[-1:0:-1]\n        print(ctrl_state)\n        qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    #qc.measure_all()\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB5264A561461", "submission_order": 12, "result": "AC", "execution_time": "2314 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #   qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if n > 1:\n\n        if ctrl_state[0] == '0':\n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.x(0)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n            qc.x(0)\n        \n        else : \n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    #qc.measure_all()\n    else :\n        if L == 0:\n            qc.x(0)\n        qc.p(theta , 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB6435BAB8C51", "submission_order": 1, "result": "RE", "execution_time": "1521 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    qc.append(RZGate().control(n - 1), range(n))\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB6435BAB8C51", "submission_order": 2, "result": "WA", "execution_time": "1624 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    if n==1:\n        qc.rz(-theta*2,0)\n    else:\n        qc.append(RZGate(-theta*2).control(n - 1), range(n))\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB6435BAB8C51", "submission_order": 3, "result": "RE", "execution_time": "2212 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB6435BAB8C51", "submission_order": 4, "result": "WA", "execution_time": "1568 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AB6435BAB8C51", "submission_order": 5, "result": "AC", "execution_time": "1882 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #qc.h(range(n))\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta,0)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if (L>>i)&1==0:\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ABF4AAFFDC491", "submission_order": 1, "result": "RE", "execution_time": "2467 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n, L, theta) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tif ~L >> i & 1:\n\t\t\tqc.x(i)\n\tqc.mcp(theta, list(range(n - 1)), n - 1)\n\tfor i in range(n):\n\t\tif ~L >> i & 1:\n\t\t\tqc.x(i)\n\treturn qc\n'''"}
{"problem": "QPC002_B2", "user": "ABF4AAFFDC491", "submission_order": 2, "result": "AC", "execution_time": "2363 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n, L, theta) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tif ~L >> i & 1:\n\t\t\tqc.x(i)\n\tif n == 1:\n\t\tqc.p(theta, n - 1)\n\telse:\n\t\tqc.mcp(theta, list(range(n - 1)), n - 1)\n\tfor i in range(n):\n\t\tif ~L >> i & 1:\n\t\t\tqc.x(i)\n\treturn qc\n'''"}
{"problem": "QPC002_B2", "user": "AC4D06CC39B86", "submission_order": 1, "result": "RE", "execution_time": "1423 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Convert L to binary string in little-endian format\n    L_bin = format(L, f'0{n}b')[::-1]\n    \n    # Create control list for multi-controlled phase gate\n    controls = []\n    for i in range(n):\n        if L_bin[i] == '1':\n            controls.append(i)\n        else:\n            qc.x(i)  # Apply X gate for 0 bits\n            controls.append(i)\n    \n    # Apply multi-controlled phase gate\n    phase_gate = MCPhaseGate(theta, len(controls))\n    qc.append(phase_gate, controls)\n    \n    # Undo X gates\n    for i in range(n):\n        if L_bin[i] == '0':\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC4D06CC39B86", "submission_order": 2, "result": "RE", "execution_time": "1182 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Convert L to binary string in little-endian format\n    L_bin = format(L, f'0{n}b')[::-1]\n    \n    # Create control list for multi-controlled phase gate\n    controls = []\n    for i in range(n):\n        if L_bin[i] == '1':\n            controls.append(i)\n        else:\n            qc.x(i)  # Apply X gate for 0 bits\n            controls.append(i)\n    \n    # Apply multi-controlled phase gate\n    phase_gate = MCPhaseGate(theta, num_ctrl_qubits=len(controls) - 1)\n    qc.append(phase_gate, controls)\n    \n    # Undo X gates\n    for i in range(n):\n        if L_bin[i] == '0':\n            qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC4D06CC39B86", "submission_order": 3, "result": "WA", "execution_time": "1985 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if (1 << i) & L:\n            qc.x(i)\n\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n\n    for i in range(n):\n        if (1 << i) & L:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC4D06CC39B86", "submission_order": 4, "result": "AC", "execution_time": "2398 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        if not (1 << i) & L:\n            qc.x(i)\n \n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if not (1 << i) & L:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC590999243A8", "submission_order": 1, "result": "AC", "execution_time": "1656 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (1 << i) & L == 0:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, n - 1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if (1 << i) & L == 0:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 1, "result": "RE", "execution_time": "1226 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # 全部1になっている物を反転\n    def reverse(qubits,qc,theta):\n        if qubits>1:\n            qc.append(RZGate(theta).control(qubits - 1), range(qubits))\n        else:\n            qc.z(0)\n    \n    # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n    to_calcable(n,qc,L)\n    reverse(n,qc,theta*2)\n    to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 2, "result": "WA", "execution_time": "1356 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # 全部1になっている物を反転\n    def reverse(qubits,qc,theta):\n        if qubits>1:\n            qc.append(RZGate(theta).control(qubits - 1), range(qubits))\n        else:\n            qc.z(0)\n    \n    # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n    to_calcable(n,qc,L)\n    reverse(n,qc,theta*2)\n    to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 3, "result": "RE", "execution_time": "1093 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==0 and L==1:\n        qc.rz(theta*2,0)\n    else:\n        raise Exception\n    \n    # # 全部1になっている物を反転\n    # def reverse(qubits,qc,theta):\n    #     if qubits>1:\n    #         qc.append(RZGate(theta).control(qubits - 1), range(qubits))\n    #     else:\n    #         qc.rz(theta,0)\n    \n    # # ある値をall_1に変更する操作\n    # def to_calcable(qubits,qc,n):\n    #     for i in range(qubits):\n    #         if not (n&(1<<i)):\n    #             qc.x(i)\n    # to_calcable(n,qc,L)\n    # reverse(n,qc,theta*2)\n    # to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 4, "result": "RE", "execution_time": "1195 ms", "memory": "140 MiB", "code": "'''python\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1 and L==1:\n        qc.rz(theta*2,0)\n    else:\n        raise Exception\n    \n    # # 全部1になっている物を反転\n    # def reverse(qubits,qc,theta):\n    #     if qubits>1:\n    #         qc.append(RZGate(theta).control(qubits - 1), range(qubits))\n    #     else:\n    #         qc.rz(theta,0)\n    \n    # # ある値をall_1に変更する操作\n    # def to_calcable(qubits,qc,n):\n    #     for i in range(qubits):\n    #         if not (n&(1<<i)):\n    #             qc.x(i)\n    # to_calcable(n,qc,L)\n    # reverse(n,qc,theta*2)\n    # to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 5, "result": "RE", "execution_time": "1053 ms", "memory": "141 MiB", "code": "'''python\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n==1 and L==0:\n        qc.x(0)\n        qc.rz(theta*2,0)\n        qc.x(0)\n    else:\n        raise Exception\n    \n    # # 全部1になっている物を反転\n    # def reverse(qubits,qc,theta):\n    #     if qubits>1:\n    #         qc.append(RZGate(theta).control(qubits - 1), range(qubits))\n    #     else:\n    #         qc.rz(theta,0)\n    \n    # # ある値をall_1に変更する操作\n    # def to_calcable(qubits,qc,n):\n    #     for i in range(qubits):\n    #         if not (n&(1<<i)):\n    #             qc.x(i)\n    # to_calcable(n,qc,L)\n    # reverse(n,qc,theta*2)\n    # to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 6, "result": "WA", "execution_time": "1338 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:   \n    \n    # # 全部1になっている物を反転\n    def reverse(qubits,qc,theta):\n        if qubits>1:\n            qc.append(RZGate(theta).control(qubits - 1), range(qubits))\n        else:\n            qc.rz(theta,0)\n    \n    # # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n    to_calcable(n,qc,L)\n    reverse(n,qc,-theta*2)\n    to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 7, "result": "RE", "execution_time": "2297 ms", "memory": "185 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:   \n    \n    # # 全部1になっている物を反転\n    def reverse(qubits,qc,theta):\n        if qubits>1:\n            qc.append(RZGate(theta).control(qubits - 1), range(qubits))\n        else:\n            raise Exception\n            qc.rz(theta,0)\n    \n    # # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n\n    to_calcable(n,qc,L)\n    reverse(n,qc,-theta*2)\n    to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 8, "result": "WA", "execution_time": "1393 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==0:\n        qc.x(0)\n        qc.rz(-theta*2,0)\n        qc.x(0)\n    else:\n        qc.rz(-theta*2,0)\n        \n    \n    # # 全部1になっている物を反転\n    # def reverse(qubits,qc,theta):\n    #     if qubits>1:\n    #         qc.append(RZGate(theta).control(qubits - 1), range(qubits))\n    #     else:\n    #         qc.rz(theta,0)\n    \n    # # # ある値をall_1に変更する操作\n    # def to_calcable(qubits,qc,n):\n    #     for i in range(qubits):\n    #         if not (n&(1<<i)):\n    #             qc.x(i)\n\n    # to_calcable(n,qc,L)\n    # reverse(n,qc,-theta*2)\n    # to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 9, "result": "RE", "execution_time": "1103 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==0:\n        qc.x(0)\n        qc.rz(-theta*2,0)\n        qc.x(0)\n    else:\n        raise Exception\n        qc.rz(-theta*2,0) \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 10, "result": "RE", "execution_time": "1214 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==0 and n==1:\n        qc.x(0)\n        qc.rz(-theta*2,0)\n        qc.x(0)\n    else:\n        raise Exception\n        qc.rz(-theta*2,0) \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 11, "result": "RE", "execution_time": "1028 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==0 and n==1:\n        qc.rz(-theta*2,0)\n    else:\n        raise Exception\n        qc.rz(-theta*2,0) \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 12, "result": "RE", "execution_time": "1167 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==0 and n==1:\n        qc.rz(-theta*2,0)\n        qc.x(0)\n    else:\n        raise Exception\n        qc.rz(-theta*2,0) \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 13, "result": "RE", "execution_time": "1530 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if L==0 and n==1:\n        qc.x(0)\n        qc.p(theta*2,0)\n        qc.x(0)\n    else:\n        raise Exception\n        qc.rz(-theta*2,0) \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 14, "result": "RE", "execution_time": "1084 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # 全部1になっている物を反転\n    def reverse(qubits,qc,theta):\n        if qubits>1:\n            qc.append(PhaseGate(theta).control(qubits - 1), range(qubits))\n        else:\n            qc.p(theta,0)\n    \n    # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n    to_calcable(n,qc,L)\n    reverse(n,qc,theta)\n    to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC6DEF08A895D", "submission_order": 15, "result": "AC", "execution_time": "2186 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # 全部1になっている物を反転\n    def reverse(qubits,qc,theta):\n        if qubits>1:\n            qc.append(PhaseGate(theta).control(qubits - 1), range(qubits))\n        else:\n            qc.p(theta,0)\n    \n    # ある値をall_1に変更する操作\n    def to_calcable(qubits,qc,n):\n        for i in range(qubits):\n            if not (n&(1<<i)):\n                qc.x(i)\n    to_calcable(n,qc,L)\n    reverse(n,qc,theta)\n    to_calcable(n,qc,L)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC775B851865D", "submission_order": 1, "result": "RE", "execution_time": "1795 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import MCPhaseGate\n#from qiskit.quantum_info import Statevector\n\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #qc.x(0)\n    mcphase_gate = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i) & 1 == 0:\n            qc.x(i)\n    qc.append(mcphase_gate, range(0,n)) \n    for i in range(n):\n        if (L>>i) & 1 == 0:\n            qc.x(i)\n\n    return qc\n\nqc = solve(4,1,np.pi/4.0)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_B2", "user": "AC775B851865D", "submission_order": 2, "result": "RE", "execution_time": "2003 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import MCPhaseGate\n#from qiskit.quantum_info import Statevector\n\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #qc.x(0)\n    if n==1:\n        if L == 0:\n            qc.x(0)\n            qc.p(theta,0)\n            qc.x(0)\n        else:\n            qc.p(theta,0)\n        return\n    mcphase_gate = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i) & 1 == 0:\n            qc.x(i)\n    qc.append(mcphase_gate, range(0,n)) \n    for i in range(n):\n        if (L>>i) & 1 == 0:\n            qc.x(i)\n\n    return qc\n\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_B2", "user": "AC775B851865D", "submission_order": 3, "result": "AC", "execution_time": "2674 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import MCPhaseGate\n#from qiskit.quantum_info import Statevector\n\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #qc.x(0)\n    if n==1:\n        if L == 0:\n            qc.x(0)\n            qc.p(theta,0)\n            qc.x(0)\n        else:\n            qc.p(theta,0)\n        return qc\n    mcphase_gate = MCPhaseGate(theta, num_ctrl_qubits=n-1)\n    # Write your code here:\n    for i in range(n):\n        if (L>>i) & 1 == 0:\n            qc.x(i)\n    qc.append(mcphase_gate, range(0,n)) \n    for i in range(n):\n        if (L>>i) & 1 == 0:\n            qc.x(i)\n\n    return qc\n\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_B2", "user": "AC98A11CD0A00", "submission_order": 1, "result": "WA", "execution_time": "1319 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        # apply  gate\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC98A11CD0A00", "submission_order": 2, "result": "WA", "execution_time": "1626 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(n-1-i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        # apply  gate\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC98A11CD0A00", "submission_order": 3, "result": "WA", "execution_time": "1518 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # qc.h(range(n))\n\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(n-1-i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        # apply  gate\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC98A11CD0A00", "submission_order": 4, "result": "AC", "execution_time": "2121 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.reverse_bits()\n\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        # apply  gate\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if not ((L >> i) & 1):\n            qc.x(i)\n\n    qc.reverse_bits()\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AC9EB584AB69F", "submission_order": 1, "result": "RE", "execution_time": "1638 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(L)\n    qc.rz(2*theta, L)\n    qc.x(L)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ACAE25060B085", "submission_order": 1, "result": "AC", "execution_time": "2372 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ACFA4BDB72593", "submission_order": 1, "result": "AC", "execution_time": "2055 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U1Gate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (L>>i & 1):\n            qc.x(i)\n\n    if n==1:\n        qc.append(U1Gate(theta), range(1))\n    else:\n        qc.append(U1Gate(theta).control(n-1), range(n))\n\n    for i in range(n):\n        if not (L>>i & 1):\n            qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AD1C1092B1803", "submission_order": 1, "result": "RE", "execution_time": "1136 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    x = []\n    a = L\n    i=n-1\n    while a:\n        if a%2:\n            x.append(i)\n        a//=2\n        i-=1\n    x=x[::-1]\n    qc.h(-1)\n    qc.mcrx(theta*2,x[:-1],x[-1])\n    qc.h(-1)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AD23E9C129B2B", "submission_order": 1, "result": "RE", "execution_time": "2003 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(i for i in range(n))\n\n    if n>=2:\n        qc.cx(0,1)\n    if n>2:\n        ent_num=1\n        ent_num_tmp=1\n        while(True):\n            for i in range(ent_num+1):\n                qc.cx(i, ent_num+1+i)\n                ent_num_tmp+=1\n\n                if ent_num+i+1==n-1:\n                    break\n            else:\n                ent_num=ent_num_tmp\n                continue\n            break\n\n    qc.mcp(theta,[i for i in range(n-1)],n-1)\n    \n    L_bin=format(L, '0'+str(n)+'b')\n    for i, l in enumerate(L_bin):\n        if l=='0':\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AD23E9C129B2B", "submission_order": 2, "result": "RE", "execution_time": "2000 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(i for i in range(n))\n\n    if n>=2:\n        qc.cx(0,1)\n    if n>2:\n        ent_num=1\n        ent_num_tmp=1\n        while(True):\n            for i in range(ent_num+1):\n                qc.cx(i, ent_num+1+i)\n                ent_num_tmp+=1\n\n                if ent_num+i+1==n-1:\n                    break\n            else:\n                ent_num=ent_num_tmp\n                continue\n            break\n\n    qc.mcp(theta,[i for i in range(n-1)],n-1)\n    \n    L_bin=format(L, '0'+str(n)+'b')\n    L_bin=L_bin[::-1]\n    for i, l in enumerate(L_bin):\n        if l=='0':\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AD3DF2F6B039E", "submission_order": 1, "result": "WA", "execution_time": "2531 ms", "memory": "161 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import RZGate\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bits = []\n\n    i = 0\n    while L:\n        if L & 1 == 0:\n            bits.append(i)\n        i += 1\n        L >>= 1\n\n    zero = QuantumRegister(1)\n    qc.add_bits(zero)\n\n    for idx in bits:\n        qc.x(idx)\n    qc.append(RZGate(-theta*2).control(n), range(n + 1))\n    for idx in bits:\n        qc.x(idx)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AD3DF2F6B039E", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import RZGate\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    bits = []\n\n    for i in range(n):\n        if L & (1 << i) == 0:\n            bits.append(i)\n        i += 1\n\n    zero = QuantumRegister(1)\n    qc.add_bits(zero)\n\n    for idx in bits:\n        qc.x(idx)\n    qc.append(RZGate(-theta*2).control(n), range(n + 1))\n    for idx in bits:\n        qc.x(idx)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADA6DC5719FA2", "submission_order": 1, "result": "RE", "execution_time": "1987 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Rz gate to the qubit\n    qc.rz(theta, 0)  # Apply Rz gate with angle theta to qubit 0\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADA6DC5719FA2", "submission_order": 2, "result": "WA", "execution_time": "2235 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Convert L to binary and apply the phase shift\n    # L is in little-endian format, so we need to apply the phase to the qubits in reverse order\n    binary_representation = format(L, '0' + str(n) + 'b')  # Get binary representation of L with n bits\n    \n    # Apply the phase shift only if the state corresponds to L\n    # The qubits are in little-endian order, so we need to apply the phase to the qubits in reverse order\n    for i in range(n):\n        if binary_representation[i] == '1':\n            qc.x(i)  # Flip the qubit to |1> if the corresponding bit is 1\n    \n    # Apply the phase shift\n    qc.rz(theta, 0)  # Apply the phase to the first qubit (which corresponds to |L>)\n    \n    # Uncompute the qubits to return to the original state\n    for i in range(n):\n        if binary_representation[i] == '1':\n            qc.x(i)  # Flip back to |0> if it was flipped to |1>\n    \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADB6D47F045EF", "submission_order": 1, "result": "RE", "execution_time": "1524 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.x(n, n)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADC692B9F95AA", "submission_order": 1, "result": "WA", "execution_time": "1637 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    log=[]\n    for j,x in enumerate(f\"{L:0{n}b}\"[::-1]):\n        if x==\"0\":\n            log.append(j)\n            qc.x(j)\n\n    if n!=1:\n        qc.append(PhaseGate(theta).control(n-1), range(n))\n        qc.global_phase = theta\n    else:\n        qc.z(0)\n        qc.global_phase = theta\n\n    for j in log:\n        qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADC692B9F95AA", "submission_order": 2, "result": "RE", "execution_time": "2720 ms", "memory": "183 MiB", "code": "'''python\n# B2\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    log=[]\n    for j,x in enumerate(f\"{L:0{n}b}\"[::-1]):\n        if x==\"0\":\n            log.append(j)\n            qc.x(j)\n\n    if n!=1:\n        qc.append(PhaseGate(theta).control(n-1), range(n))\n        qc.global_phase = theta\n    else:\n        qc.p(0)\n        qc.global_phase = theta\n\n    for j in log:\n        qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADC692B9F95AA", "submission_order": 3, "result": "AC", "execution_time": "2020 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    log=[]\n    for j,x in enumerate(f\"{L:0{n}b}\"[::-1]):\n        if x==\"0\":\n            log.append(j)\n            qc.x(j)\n\n    if n!=1:\n        qc.append(PhaseGate(theta).control(n-1), range(n))\n        qc.global_phase = theta\n    else:\n        qc.p(theta,0)\n        qc.global_phase = theta\n\n    for j in log:\n        qc.x(j)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADD109A66C727", "submission_order": 1, "result": "WA", "execution_time": "1340 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        if (L >> i & 1):\n            qc.p(theta, i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADD109A66C727", "submission_order": 2, "result": "RE", "execution_time": "1679 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n    if n == 1:\n        qc.p(theta)\n    else:\n        qc.append(qlib.PhaseGate(theta).control(n - 1), range(n))\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADD109A66C727", "submission_order": 3, "result": "WA", "execution_time": "1474 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(qlib.PhaseGate(theta).control(n - 1), range(n))\n    for l in range(L):\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADD109A66C727", "submission_order": 4, "result": "AC", "execution_time": "2277 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.append(qlib.PhaseGate(theta).control(n - 1), range(n))\n    for i in range(n):\n        # check if i-th bit of l is 0 or 1\n        if not ((L >> i) & 1):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADF60381639B3", "submission_order": 1, "result": "WA", "execution_time": "1313 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if ((L >> i) & 1) == 0:\n            qc.x(i)\n        qc.rz(-2 * theta, i)\n        if ((L >> i) & 1) == 0:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADF60381639B3", "submission_order": 2, "result": "WA", "execution_time": "1178 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if ((L >> i) & 1) == 1:\n            qc.x(i)\n        qc.rz(-2 * theta, i)\n        if ((L >> i) & 1) == 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADF60381639B3", "submission_order": 3, "result": "RE", "execution_time": "1372 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.x([0, 2])\n    # Write your code here:\n    for i in range(n):\n        if ((L >> i) & 1) == 0:\n            qc.x(i)\n\n    mp = PhaseGate(theta).control(n - 1)\n    qc.append(mp, range(n))\n\n    for i in range(n):\n        if ((L >> i) & 1) == 0:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADF60381639B3", "submission_order": 4, "result": "RE", "execution_time": "2217 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.x([0, 2])\n    # Write your code here:\n    for i in range(n):\n        if ((L >> i) & 1) == 0:\n            qc.x(i)\n\n    mp = PhaseGate(theta).control(n - 1)\n    qc.append(mp, range(n))\n\n    for i in range(n):\n        if ((L >> i) & 1) == 0:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "ADF60381639B3", "submission_order": 5, "result": "AC", "execution_time": "2762 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n \ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.x([0, 2])\n    # Write your code here:\n    for i in range(n):\n        if ((L >> i) & 1) == 0:\n            qc.x(i)\n\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        mp = PhaseGate(theta).control(n - 1)\n        qc.append(mp, range(n))\n\n    for i in range(n):\n        if ((L >> i) & 1) == 0:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE21A0E970A7C", "submission_order": 1, "result": "WA", "execution_time": "1100 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 1:\n            qc.x(i)\n\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE21A0E970A7C", "submission_order": 2, "result": "WA", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(0, n):\n        qc.h(i)\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 1:\n            qc.x(i)\n\n    qc.x(0)\n    qc.p(theta, 0)\n    qc.x(0)\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE21A0E970A7C", "submission_order": 3, "result": "WA", "execution_time": "1274 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # for i in range(0, n):\n    #     qc.h(i)\n\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(1, n)), 0)\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE21A0E970A7C", "submission_order": 4, "result": "RE", "execution_time": "1270 ms", "memory": "140 MiB", "code": "'''python\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # for i in range(0, n):\n    #     qc.h(i)\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 0:\n            qc.x(i)\n\n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(1, n)), 0)\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE21A0E970A7C", "submission_order": 5, "result": "AC", "execution_time": "1811 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # for i in range(0, n):\n    #     qc.h(i)\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 0:\n            qc.x(i)\n\n    if n == 1:\n        qc.p(theta, 0)\n    elif n == 2:\n        qc.cp(theta, 1, 0)\n    else:\n        qc.mcp(theta, list(range(1, n)), 0)\n\n    for i in range(0, n):\n        if (L >> i) & 1 == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE9A736FE1E50", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bin_L = bin(L)\n    bin_L.zfill(n) # big endian\n    bin_L = bin_L[::-1] # little endian\n\n    one_list = []\n    zero_list= []\n    for i in range(n):\n        if bin_L[i] == '1':\n            one_list.append(i)\n        else:\n            zero_list.append(i)\n    \n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    # ctl_len = len(one_list)-1 if n-1 in one_list else len(one_list)\n    # if bin_L[n-1]=='0':\n    #     pass\n    # else:\n    #     qc.\n    qc.append(PGate(theta).control(n-1), range(n))\n\n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE9A736FE1E50", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.circuit.library.standard_gates import PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bin_L = bin(L)\n    bin_L.zfill(n) # big endian\n    bin_L = bin_L[::-1] # little endian\n    for i in range(n):\n        qc.h(i)\n\n    one_list = []\n    zero_list= []\n    for i in range(n):\n        if bin_L[i] == '1':\n            one_list.append(i)\n        else:\n            zero_list.append(i)\n    \n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    # ctl_len = len(one_list)-1 if n-1 in one_list else len(one_list)\n    # if bin_L[n-1]=='0':\n    #     pass\n    # else:\n    #     qc.\n    # qc.append(PGate(theta).control(n-1), range(n))\n    if n-1 in one_list:\n        qc.x(n-1)\n\n    qc.mcx(list(range(n-1)), n-1)\n    qc.p(theta, n-1)\n    qc.mcx(list(range(n-1)), n-1)\n\n    if n-1 in one_list:\n        qc.(n-1)\n\n\n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE9A736FE1E50", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.circuit.library.standard_gates import PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bin_L = bin(L)\n    bin_L.zfill(n) # big endian\n    bin_L = bin_L[::-1] # little endian\n    for i in range(n):\n        qc.h(i)\n\n    one_list = []\n    zero_list= []\n    for i in range(n):\n        if bin_L[i] == '1':\n            one_list.append(i)\n        else:\n            zero_list.append(i)\n\n    if n==1:\n        if bin_L=='0':\n            qc.x(0)\n        qc.p(theta, 0)\n        if bin_L=='0':\n            qc.x(0)\n        return qc\n\n    \n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    # ctl_len = len(one_list)-1 if n-1 in one_list else len(one_list)\n    # if bin_L[n-1]=='0':\n    #     pass\n    # else:\n    #     qc.\n    # qc.append(PGate(theta).control(n-1), range(n))\n    if n-1 in one_list:\n        qc.x(n-1)\n\n    qc.mcx(list(range(n-1)), n-1)\n    qc.p(theta, n-1)\n    qc.mcx(list(range(n-1)), n-1)\n\n    if n- in one_list:\n        qc.(n-1)\n\n\n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE9A736FE1E50", "submission_order": 4, "result": "RE", "execution_time": "2373 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.circuit.library.standard_gates import PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bin_L = bin(L)\n    bin_L.zfill(n) # big endian\n    bin_L = bin_L[::-1] # little endian\n    for i in range(n):\n        qc.h(i)\n\n    one_list = []\n    zero_list= []\n    for i in range(n):\n        if bin_L[i] == '1':\n            one_list.append(i)\n        else:\n            zero_list.append(i)\n\n    if n==1:\n        if bin_L=='0':\n            qc.x(0)\n        qc.p(theta, 0)\n        if bin_L=='0':\n            qc.x(0)\n        return qc\n\n    \n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    # ctl_len = len(one_list)-1 if n-1 in one_list else len(one_list)\n    # if bin_L[n-1]=='0':\n    #     pass\n    # else:\n    #     qc.\n    # qc.append(PGate(theta).control(n-1), range(n))\n    if n-1 in one_list:\n        qc.x(n-1)\n\n    qc.mcx(list(range(n-1)), n-1)\n    qc.p(theta, n-1)\n    qc.mcx(list(range(n-1)), n-1)\n\n    if n-1 in one_list:\n        qc.x(n-1)\n\n\n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE9A736FE1E50", "submission_order": 5, "result": "WA", "execution_time": "1137 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.circuit.library.standard_gates import PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bin_L = bin(L)\n    bin_L = bin_L[2:]\n    bin_L = bin_L.zfill(n) # big endian\n    bin_L = bin_L[::-1] # little endian\n    print(bin_L)\n    for i in range(n):\n        qc.h(i)\n\n    one_list = []\n    zero_list= []\n    for i in range(n):\n        if bin_L[i] == '1':\n            one_list.append(i)\n        else:\n            zero_list.append(i)\n\n    if n==1:\n        if bin_L=='0':\n            qc.x(0)\n        qc.p(theta, 0)\n        if bin_L=='0':\n            qc.x(0)\n        return qc\n\n    \n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    # ctl_len = len(one_list)-1 if n-1 in one_list else len(one_list)\n    # if bin_L[n-1]=='0':\n    #     pass\n    # else:\n    #     qc.\n    # qc.append(PGate(theta).control(n-1), range(n))\n    if n-1 in one_list:\n        qc.x(n-1)\n\n    qc.mcx(list(range(n-1)), n-1)\n    qc.p(theta, n-1)\n    qc.mcx(list(range(n-1)), n-1)\n\n    if n-1 in one_list:\n        qc.x(n-1)\n\n\n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE9A736FE1E50", "submission_order": 6, "result": "RE", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.circuit.library.standard_gates import PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bin_L = bin(L)\n    bin_L = bin_L[2:]\n    bin_L = bin_L.zfill(n) # big endian\n    bin_L = bin_L[::-1] # little endian\n    print(bin_L)\n    for i in range(n):\n        qc.h(i)\n\n    one_list = []\n    zero_list= []\n    for i in range(n):\n        if bin_L[i] == '1':\n            one_list.append(i)\n        else:\n            zero_list.append(i)\n\n    if n==1:\n        if bin_L=='0':\n            qc.x(0)\n        qc.p(theta, 0)\n        if bin_L=='0':\n            qc.x(0)\n        return qc\n\n    \n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    # ctl_len = len(one_list)-1 if n-1 in one_list else len(one_list)\n    # if bin_L[n-1]=='0':\n    #     pass\n    # else:\n    #     qc.\n    # qc.append(PGate(theta).control(n-1), range(n))\n    if n-1 in zero_list:\n        qc.x(n-1)\n\n    qc.mcp(list(range(n-1)), n-1)\n    # qc.mcx(list(range(n-1)), n-1)\n    # qc.p(theta, n-1)\n    # qc.mcx(list(range(n-1)), n-1)\n\n    if n-1 in zero_list:\n        qc.x(n-1)\n\n\n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE9A736FE1E50", "submission_order": 7, "result": "WA", "execution_time": "1678 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.circuit.library.standard_gates import PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bin_L = bin(L)\n    bin_L = bin_L[2:]\n    bin_L = bin_L.zfill(n) # big endian\n    bin_L = bin_L[::-1] # little endian\n    print(bin_L)\n    for i in range(n):\n        qc.h(i)\n\n    one_list = []\n    zero_list= []\n    for i in range(n):\n        if bin_L[i] == '1':\n            one_list.append(i)\n        else:\n            zero_list.append(i)\n\n    if n==1:\n        if bin_L=='0':\n            qc.x(0)\n        qc.p(theta, 0)\n        if bin_L=='0':\n            qc.x(0)\n        return qc\n\n    \n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    # ctl_len = len(one_list)-1 if n-1 in one_list else len(one_list)\n    # if bin_L[n-1]=='0':\n    #     pass\n    # else:\n    #     qc.\n    # qc.append(PGate(theta).control(n-1), range(n))\n    if n-1 in zero_list:\n        qc.x(n-1)\n\n    qc.mcp(theta, list(range(n-1)), n-1)\n    # qc.mcx(list(range(n-1)), n-1)\n    # qc.p(theta, n-1)\n    # qc.mcx(list(range(n-1)), n-1)\n\n    if n-1 in zero_list:\n        qc.x(n-1)\n\n\n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AE9A736FE1E50", "submission_order": 8, "result": "WA", "execution_time": "1649 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.circuit.library.standard_gates import PGate\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    bin_L = bin(L)\n    bin_L = bin_L[2:]\n    bin_L = bin_L.zfill(n) # big endian\n    bin_L = bin_L[::-1] # little endian\n    # print(bin_L)\n    for i in range(n):\n        qc.h(i)\n\n    one_list = []\n    zero_list= []\n    for i in range(n):\n        if bin_L[i] == '1':\n            one_list.append(i)\n        else:\n            zero_list.append(i)\n\n    if n==1:\n        if bin_L=='0':\n            qc.x(0)\n        qc.p(theta, 0)\n        if bin_L=='0':\n            qc.x(0)\n        return qc\n\n    \n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    # ctl_len = len(one_list)-1 if n-1 in one_list else len(one_list)\n    # if bin_L[n-1]=='0':\n    #     pass\n    # else:\n    #     qc.\n    # qc.append(PGate(theta).control(n-1), range(n))\n    if n-1 in zero_list:\n        qc.x(n-1)\n\n    qc.mcp(theta,list(range(n-1)), n-1)\n    # qc.mcx(list(range(n-1)), n-1)\n    # qc.p(theta, n-1)\n    # qc.mcx(list(range(n-1)), n-1)\n\n    if n-1 in zero_list:\n        qc.x(n-1)\n\n\n    for i in range(n-1):\n        if i in zero_list:\n            qc.x(i)\n    \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AEA03C1691A47", "submission_order": 1, "result": "RE", "execution_time": "1106 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.mcp(theta, [ i for i in range(n) ], 0, L)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AECB704E286D2", "submission_order": 1, "result": "AC", "execution_time": "2241 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    ctrl_state = format(L, f'0{n}b')[::-1]\n\n    if n > 1:\n        for i in range(n):\n            if ctrl_state[i]=='0':\n                qc.x(i)\n        \n        #Apply MCT phase gate\n        qc.mcp(theta, [i for i in range(1,n)],0)\n\n        #Revert X gates\n        for i in range(n):\n            if ctrl_state[i]=='0':\n                qc.x(i)\n    else:\n        #For single qubit case\n        if L==0:\n            qc.x(0)\n        qc.p(theta,0)\n        if L==0:\n            qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AEE8E993EB075", "submission_order": 1, "result": "RE", "execution_time": "1187 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary = format(L, f'0{n}b')[::-1]\n    t_qubit = 0\n    c_qubits = list(range(1, n))\n\n    for i in range(n):\n      if binary[i] == '0':\n        qc.x(i)\n    qc.mcp(theta, c_qubits, t_qubit)\n    for i in range(n):\n      if binary[i] == '0':\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AEE8E993EB075", "submission_order": 2, "result": "RE", "execution_time": "1394 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary = format(L, f'0{n}b')[::-1]\n    t_qubit = 0\n    c_qubits = list(range(1, n))\n\n    for i in range(n):\n      if binary[i] == '0':\n        qc.x(i)\n    qc.mcp(theta, c_qubits, t_qubit)\n    for i in range(n):\n      if binary[i] == '0':\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AEE8E993EB075", "submission_order": 3, "result": "AC", "execution_time": "2371 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    binary = format(L, f'0{n}b')[::-1]\n    t_qubit = 0\n    c_qubits = list(range(1, n))\n\n    if n == 1:\n      if binary == '0':\n        qc.x(0)\n        qc.p(theta, 0)\n        qc.x(0)\n      else:\n        qc.p(theta, 0)\n    else:\n      for i in range(n):\n        if binary[i] == '0':\n          qc.x(i)\n      qc.mcp(theta, c_qubits, t_qubit)\n      for i in range(n):\n        if binary[i] == '0':\n          qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF0ECE38FD6F0", "submission_order": 1, "result": "RE", "execution_time": "2434 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    qc.mcp(theta, list(range(n-1)), n-1)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF0ECE38FD6F0", "submission_order": 2, "result": "AC", "execution_time": "2785 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF2F359358072", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    if not (1<<i) & L:\n        qc.x(i)\n    if n == 1:\n        qc.p(theta, n-1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n\n        if not(1<<i) & L:\n            qc.x(i) \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF2F359358072", "submission_order": 2, "result": "AC", "execution_time": "1685 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (1<<i) & L:\n            qc.x(i)\n    if n == 1:\n        qc.p(theta, n-1)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n    for i in range(n):\n\n        if not(1<<i) & L:\n            qc.x(i) \n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF36F5702058E", "submission_order": 1, "result": "WA", "execution_time": "1487 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Convert L to binary and pad with zeros to match n qubits\n    L_binary = bin(L)[2:].zfill(n)\n    \n    # Apply phase shift RZ(theta) to the target state\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    \n    # Apply the phase gate to the |L> state\n    qc.rz(theta, range(n))\n    \n    # Apply the inverse of the previous X gates to return to the original basis\n    for i, bit in enumerate(L_binary):\n        if bit == '1':\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF36F5702058E", "submission_order": 2, "result": "RE", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply a phase shift of θ to the state |L⟩\n    for i in range(n):\n        if (L >> i) & 1:\n            qc.u1(theta, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF36F5702058E", "submission_order": 3, "result": "RE", "execution_time": "1469 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply a phase shift of θ to the state |L⟩\n    for i in range(n):\n        if (L >> i) & 1:\n            qc.u1(theta, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF75933A4A7FD", "submission_order": 1, "result": "RE", "execution_time": "1226 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L_bits = [int(b) for b in format(L, f'0{n}b')][::-1]\n\n    for i, bit in enumerate(L_bits):\n        if bit == 0:\n            qc.x(qr[i])\n\n    qc.mcphase(theta, qr[:-1], qr[-1])\n\n    for i, bit in enumerate(L_bits):\n        if bit == 0:\n            qc.x(qr[i])\n\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF75933A4A7FD", "submission_order": 2, "result": "RE", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L_bits = [int(b) for b in format(L, f'0{n}b')][::-1]\n\n    for i, bit in enumerate(L_bits):\n        if bit == 0:\n            qc.x(i)\n\n    if n > 1:\n        control_qubits = list(range(n-1))\n        target_qubit = n-1\n        qc.mcphase(theta, control_qubits, target_qubit)\n    else:\n        qc.p(theta, 0)\n\n    for i, bit in enumerate(L_bits):\n        if bit == 0:\n            qc.x(i)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF75933A4A7FD", "submission_order": 3, "result": "AC", "execution_time": "2307 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L_bits = [int(b) for b in format(L, f'0{n}b')][::-1]\n\n    for i, bit in enumerate(L_bits):\n        if bit == 0:\n            qc.x(i)\n\n    if n > 1:\n        control_qubits = list(range(n-1))\n        target_qubit = n-1\n        qc.mcp(theta, control_qubits, target_qubit)\n    else:\n        qc.p(theta, 0)\n\n    for i, bit in enumerate(L_bits):\n        if bit == 0:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF7785B8795DA", "submission_order": 1, "result": "WA", "execution_time": "1037 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    qc.rz(2*theta,0)\n    qc.x(0)\n    for i in range(n):\n        if (L >> i & 1) == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF8378B352CE0", "submission_order": 1, "result": "RE", "execution_time": "1573 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not(L&(1<<i)):\n            qc.x(i)\n    qc.mcp(theta, list(range(0,n-1)), n-1)\n    for i in range(n):\n        if not(L&(1<<i)):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF8378B352CE0", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        if l==0:\n            qc.x(0)\n            qc.p(theta,0)\n            qc.x(0)\n        else:\n            qc.p(theta,0)\n        return qc\n    for i in range(n)\n        if not(L&(1<<i)):\n            qc.x(i)\n    qc.mcp(theta, list(range(0,n-1)), n-1)\n    for i in range(n):\n        if not(L&(1<<i)):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF8378B352CE0", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        if L==0:\n            qc.x(0)\n            qc.p(theta,0)\n            qc.x(0)\n        else:\n            qc.p(theta,0)\n        return qc\n    for i in range(n)\n        if not(L&(1<<i)):\n            qc.x(i)\n    qc.mcp(theta, list(range(0,n-1)), n-1)\n    for i in range(n):\n        if not(L&(1<<i)):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B2", "user": "AF8378B352CE0", "submission_order": 4, "result": "AC", "execution_time": "1754 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==1:\n        if L==0:\n            qc.x(0)\n            qc.p(theta,0)\n            qc.x(0)\n        else:\n            qc.p(theta,0)\n        return qc\n    for i in range(n):\n        if not(L&(1<<i)):\n            qc.x(i)\n    qc.mcp(theta, list(range(0,n-1)), n-1)\n    for i in range(n):\n        if not(L&(1<<i)):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A0015DA91911B", "submission_order": 1, "result": "AC", "execution_time": "1434 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A002977FE5FAE", "submission_order": 1, "result": "AC", "execution_time": "1475 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A00A41AA4CCA9", "submission_order": 1, "result": "AC", "execution_time": "1886 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A0396FFBB5939", "submission_order": 1, "result": "AC", "execution_time": "1685 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A03F7119C7E54", "submission_order": 1, "result": "AC", "execution_time": "1568 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A0B7ED7C5CAC7", "submission_order": 1, "result": "AC", "execution_time": "1421 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A0D3A4BA140A9", "submission_order": 1, "result": "AC", "execution_time": "1667 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A111E0B2A0EAC", "submission_order": 1, "result": "AC", "execution_time": "1538 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1,0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A133E0D3B1F7C", "submission_order": 1, "result": "AC", "execution_time": "1442 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A158DC8349B2D", "submission_order": 1, "result": "AC", "execution_time": "1420 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1622B4E384CB", "submission_order": 1, "result": "AC", "execution_time": "1614 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A175533CEF6D7", "submission_order": 1, "result": "AC", "execution_time": "1563 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1A2CAC01C445", "submission_order": 1, "result": "RE", "execution_time": "1455 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.x(1)\n    qc.x(2)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1A2CAC01C445", "submission_order": 2, "result": "WA", "execution_time": "1313 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1A2CAC01C445", "submission_order": 3, "result": "AC", "execution_time": "1650 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1A3C427452F2", "submission_order": 1, "result": "RE", "execution_time": "1578 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  \n  theta = math.pi/2\n  qc.rzz(theta, 0, 1)\n  qc.ryy(theta, 0, 1)\n  qc.rxx(theta, 0, 1)\n\n  #qc.global_phase = theta / 2\n  \n  return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1A3C427452F2", "submission_order": 2, "result": "AC", "execution_time": "2079 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  \n  theta = math.pi/2\n  qc.rzz(theta, 0, 1)\n  qc.ryy(theta, 0, 1)\n  qc.rxx(theta, 0, 1)\n\n  #qc.global_phase = theta / 2\n  \n  return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1C2BF63E08C9", "submission_order": 1, "result": "WA", "execution_time": "1164 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.z(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1C2BF63E08C9", "submission_order": 2, "result": "WA", "execution_time": "1249 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1C2BF63E08C9", "submission_order": 3, "result": "AC", "execution_time": "1488 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1D5A15544175", "submission_order": 1, "result": "AC", "execution_time": "1502 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A1F89ED691FD2", "submission_order": 1, "result": "AC", "execution_time": "1545 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A2043DB08349F", "submission_order": 1, "result": "AC", "execution_time": "1644 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A21C085962160", "submission_order": 1, "result": "AC", "execution_time": "1446 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A229B6C64C3C2", "submission_order": 1, "result": "AC", "execution_time": "1514 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A2C5E8B63C824", "submission_order": 1, "result": "AC", "execution_time": "1380 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A3239634548FD", "submission_order": 1, "result": "AC", "execution_time": "1465 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A32B357D73B83", "submission_order": 1, "result": "AC", "execution_time": "1613 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A331EFF8633BA", "submission_order": 1, "result": "AC", "execution_time": "1615 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A35333DC98F34", "submission_order": 1, "result": "AC", "execution_time": "1477 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A357724E5F3C3", "submission_order": 1, "result": "AC", "execution_time": "1716 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A378B2F80E56E", "submission_order": 1, "result": "AC", "execution_time": "1466 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A37E1CC8CEB16", "submission_order": 1, "result": "AC", "execution_time": "1691 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A3830F6CA148F", "submission_order": 1, "result": "AC", "execution_time": "2069 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A3A1230EB0858", "submission_order": 1, "result": "AC", "execution_time": "1415 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0, 1)  # CNOT gate with qubit 0 as control and qubit 1 as target\n    qc.cx(1, 0)  # CNOT gate with qubit 1 as control and qubit 0 as target\n    qc.cx(0, 1) \n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A3B8580CB9AF3", "submission_order": 1, "result": "AC", "execution_time": "1603 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A3BFB67C886EC", "submission_order": 1, "result": "AC", "execution_time": "1350 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A3E87874D908E", "submission_order": 1, "result": "AC", "execution_time": "1599 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A43624A8D7E07", "submission_order": 1, "result": "UGE", "execution_time": "1043 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n\n    \n    qc.swap(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A43624A8D7E07", "submission_order": 2, "result": "WA", "execution_time": "1424 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A43624A8D7E07", "submission_order": 3, "result": "WA", "execution_time": "1399 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0,1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A43624A8D7E07", "submission_order": 4, "result": "AC", "execution_time": "1988 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A450BE7DC82FB", "submission_order": 1, "result": "AC", "execution_time": "1994 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A4611E27DD1BC", "submission_order": 1, "result": "WA", "execution_time": "1056 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A4611E27DD1BC", "submission_order": 2, "result": "AC", "execution_time": "1383 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A4D2DAE53A53D", "submission_order": 1, "result": "AC", "execution_time": "1919 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A4FC93C1616AB", "submission_order": 1, "result": "AC", "execution_time": "1758 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A4FF72CBCA9F8", "submission_order": 1, "result": "AC", "execution_time": "1494 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A56A9655616E0", "submission_order": 1, "result": "AC", "execution_time": "1457 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A56B2C9686A0A", "submission_order": 1, "result": "WA", "execution_time": "1916 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A576A6B3A5353", "submission_order": 1, "result": "AC", "execution_time": "1562 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A590F12569225", "submission_order": 1, "result": "UGE", "execution_time": "1453 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A590F12569225", "submission_order": 2, "result": "AC", "execution_time": "1407 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A5BBB88FA1786", "submission_order": 1, "result": "WA", "execution_time": "1303 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A5BBB88FA1786", "submission_order": 2, "result": "AC", "execution_time": "1567 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A5CAD35A87AD4", "submission_order": 1, "result": "AC", "execution_time": "1438 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A5F194F38AC98", "submission_order": 1, "result": "AC", "execution_time": "1507 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A5F4958E16AC4", "submission_order": 1, "result": "WA", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)  # Flip the first qubit to |1>\n    qc.h(1)\n    qc.cx(0, 1)  # First CNOT: qubit 0 -> qubit 1\n    qc.cx(1, 0)  # Second CNOT: qubit 1 -> qubit 0\n    qc.cx(0, 1)  # Third CNOT: qubit 0 -> qubit 1  \n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A5F4958E16AC4", "submission_order": 2, "result": "AC", "execution_time": "1549 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A5FD32C581C62", "submission_order": 1, "result": "AC", "execution_time": "2071 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Apply CNOT from qubit 0 to qubit 1\n    qc.cx(0, 1)\n    \n    # Step 2: Apply CNOT from qubit 1 to qubit 0\n    qc.cx(1, 0)\n    \n    # Step 3: Apply CNOT from qubit 0 to qubit 1 again\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A64597814C4A1", "submission_order": 1, "result": "AC", "execution_time": "1979 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A657AD3AE3FBA", "submission_order": 1, "result": "AC", "execution_time": "1485 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Implement SWAP using 3 CNOT gates\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A661955560265", "submission_order": 1, "result": "AC", "execution_time": "1822 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1,0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A6C936C452315", "submission_order": 1, "result": "AC", "execution_time": "1373 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A71AB49EC526C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.quantum_info.operators import Operator\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    swap = Operator([\n        [1, 0, 0, 0],\n        [0, 0, 1, 0],\n        [0, 1, 0, 0],\n        [0, 0, 0, 1]\n    ])\n    qc.unitary(cswap, [0, 1], label='swap')\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A71AB49EC526C", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.quantum_info.operators import Operator\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    sw = Operator([\n        [1, 0, 0, 0],\n        [0, 0, 1, 0],\n        [0, 1, 0, 0],\n        [0, 0, 0, 1]\n    ])\n    qc.unitary(sw, [0, 1], label='sw')\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A71AB49EC526C", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.quantum_info.operators import Operator\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A71AB49EC526C", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.quantum_info.operators import Operator\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.reverse_bits()\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A73B108E612D2", "submission_order": 1, "result": "RE", "execution_time": "1061 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    # 1 0 2\n\n    qc.x(1)\n    qc.x(1,0)\n    qc.x(1)\n    # 2 0 1\n\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    # 0 2 1\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A73B108E612D2", "submission_order": 2, "result": "AC", "execution_time": "1431 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    # 1 0 2\n\n    qc.x(1)\n    qc.cx(1,0)\n    qc.x(1)\n    # 2 0 1\n\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    # 0 2 \n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A762E374C12F3", "submission_order": 1, "result": "AC", "execution_time": "2288 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n \n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A769227C0A7B1", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, AncillaRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    ancilla = AncillaRegister(1)\n    qc.add_register(ancilla)\n    qc.cx(0, 2)\n    qc.cx(1, 2)\n\n    qc.cx(2, 0)\n    qc.cx(2, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A769227C0A7B1", "submission_order": 2, "result": "QLE", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    ancilla = QuantumRegister(1)\n    qc.add_register(ancilla)\n    qc.cx(0, 2)\n    qc.cx(1, 2)\n\n    qc.cx(2, 0)\n    qc.cx(2, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A769227C0A7B1", "submission_order": 3, "result": "RE", "execution_time": "1385 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    ancilla = QuantumRegisterr(1)\n    qc.add_register(ancilla)\n    qc.cx(0, 2)\n    qc.cx(1, 2)\n\n    qc.cx(2, 0)\n    qc.cx(2, 1)\n\n    qc.qregs = qc.qregs[0]\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A769227C0A7B1", "submission_order": 4, "result": "AC", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A770E781AA942", "submission_order": 1, "result": "RE", "execution_time": "1702 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1,2)\n    qc.cx(2,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A770E781AA942", "submission_order": 2, "result": "WA", "execution_time": "1913 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A784BA0B1A2A0", "submission_order": 1, "result": "AC", "execution_time": "1688 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A78C2F091E332", "submission_order": 1, "result": "UGE", "execution_time": "1122 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7AFB89060F25", "submission_order": 1, "result": "AC", "execution_time": "1836 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    # Apply the sequence of CNOT gates to swap the qubit states\n    qc.cx(0, 1)  # First CNOT: control qubit 0, target qubit 1\n    qc.cx(1, 0)  # Second CNOT: control qubit 1, target qubit 0\n    qc.cx(0, 1)  # Third CNOT: control qubit 0, target qubit 1\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7B6728860797", "submission_order": 1, "result": "AC", "execution_time": "1401 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7B8CFDB78C51", "submission_order": 1, "result": "RE", "execution_time": "1872 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.cx(1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7B8CFDB78C51", "submission_order": 2, "result": "WA", "execution_time": "2359 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.cx(0,1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7B8CFDB78C51", "submission_order": 3, "result": "AC", "execution_time": "2020 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7C1C008D9BCC", "submission_order": 1, "result": "AC", "execution_time": "1729 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7D3707B9F1EE", "submission_order": 1, "result": "AC", "execution_time": "1960 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7D5274F9BF72", "submission_order": 1, "result": "AC", "execution_time": "1458 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7DF93091AE90", "submission_order": 1, "result": "AC", "execution_time": "1601 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A7FDD95067519", "submission_order": 1, "result": "AC", "execution_time": "1387 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A8B5C4F29DE93", "submission_order": 1, "result": "AC", "execution_time": "1514 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A8D29193C5257", "submission_order": 1, "result": "AC", "execution_time": "1467 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A8EC45CD1C764", "submission_order": 1, "result": "AC", "execution_time": "1432 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A8EEA109DA2CA", "submission_order": 1, "result": "AC", "execution_time": "1664 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A8FE7978A67DC", "submission_order": 1, "result": "AC", "execution_time": "1647 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A900122B6CA41", "submission_order": 1, "result": "AC", "execution_time": "1922 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2, 1, math.pi / 2)\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     sv = Statevector.from_label('++')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_B3", "user": "A91882CF24828", "submission_order": 1, "result": "RE", "execution_time": "1487 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(qubit1, qubit2)\n    qc.cx(qubit2, qubit1)\n    qc.cx(qubit1, qubit2)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A91882CF24828", "submission_order": 2, "result": "AC", "execution_time": "1614 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A92D6C865894A", "submission_order": 1, "result": "AC", "execution_time": "1477 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    #a1 a3 swap\n    qc.cx(0,1)\n    #a1 a2 swap\n    qc.cx(1,0)\n    #a2 a3 swap\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A93A961CC701F", "submission_order": 1, "result": "WA", "execution_time": "1686 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    for i in range(2):\n        qc.x(i)\n        qc.y(i)\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A93A961CC701F", "submission_order": 2, "result": "AC", "execution_time": "1570 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A979140B82563", "submission_order": 1, "result": "WA", "execution_time": "1023 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A979140B82563", "submission_order": 2, "result": "WA", "execution_time": "1122 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A979140B82563", "submission_order": 3, "result": "WA", "execution_time": "1059 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(range(2))\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A979140B82563", "submission_order": 4, "result": "WA", "execution_time": "1045 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A979140B82563", "submission_order": 5, "result": "WA", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A979140B82563", "submission_order": 6, "result": "AC", "execution_time": "1668 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # qc.h(range(2))\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A979140B82563", "submission_order": 7, "result": "AC", "execution_time": "1668 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # qc.h(range(2))\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A990112BC0F2E", "submission_order": 1, "result": "AC", "execution_time": "1449 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A99C716C76EB1", "submission_order": 1, "result": "AC", "execution_time": "1399 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9B1E5E5D9B46", "submission_order": 1, "result": "UGE", "execution_time": "1072 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.swap(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9B1E5E5D9B46", "submission_order": 2, "result": "AC", "execution_time": "1902 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9BABA1EE6915", "submission_order": 1, "result": "AC", "execution_time": "1781 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0, 1) \n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9C5BDFC929E5", "submission_order": 1, "result": "UGE", "execution_time": "1491 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.swap(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9C5BDFC929E5", "submission_order": 2, "result": "RE", "execution_time": "1077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.s(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9C5BDFC929E5", "submission_order": 3, "result": "WA", "execution_time": "1345 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    # qc.s(0,1)\n    # temp = qc(0)\n    qc.cx(0,1)\n    qc.cx(0,1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9C5BDFC929E5", "submission_order": 4, "result": "WA", "execution_time": "1070 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    # qc.s(0,1)\n    # temp = qc(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9C5BDFC929E5", "submission_order": 5, "result": "AC", "execution_time": "1491 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "A9D95B24DF1B7", "submission_order": 1, "result": "AC", "execution_time": "1964 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\tqc.cx(0, 1)\n\tqc.cx(1, 0)\n\tqc.cx(0, 1)\n\treturn qc\n'''"}
{"problem": "QPC002_B3", "user": "A9F4266B3B964", "submission_order": 1, "result": "AC", "execution_time": "1491 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AA27040777304", "submission_order": 1, "result": "AC", "execution_time": "1494 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AA2CD6152DCDB", "submission_order": 1, "result": "AC", "execution_time": "1499 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AA79A66B49699", "submission_order": 1, "result": "AC", "execution_time": "1655 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AA7F0A90095E2", "submission_order": 1, "result": "WA", "execution_time": "1062 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AA7F0A90095E2", "submission_order": 2, "result": "AC", "execution_time": "1460 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AA9F4B464C278", "submission_order": 1, "result": "AC", "execution_time": "1519 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AAA0B0B5A0E81", "submission_order": 1, "result": "AC", "execution_time": "1551 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # a0 a1 a2 a3\n\n    qc.cx(1, 0)\n    # a0 a1 a3 a2\n\n    qc.cx(0, 1)\n    # a0 a2 a3 a1\n\n    qc.cx(1, 0)\n    # a0 a2 a1 a3\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AAA8DFF56320E", "submission_order": 1, "result": "AC", "execution_time": "1588 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AAC39E409AD0E", "submission_order": 1, "result": "AC", "execution_time": "1538 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AAFCCAC21EADD", "submission_order": 1, "result": "AC", "execution_time": "1870 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import MCPhaseGate\n#from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    #qc.h(0)\n    # Write your code here:\n    qc.cx(1,0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n \n    return qc\n\n#print(Statevector(qc)) #こことimportを消す\n\nqc = solve()\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_B3", "user": "AB68EDD072140", "submission_order": 1, "result": "AC", "execution_time": "1730 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AB829E7EF034C", "submission_order": 1, "result": "UGE", "execution_time": "1464 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AB829E7EF034C", "submission_order": 2, "result": "AC", "execution_time": "1765 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AB8B7D7A03764", "submission_order": 1, "result": "RE", "execution_time": "1180 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.cnot(0, 1)\n  qc.cnot(1, 0)\n  qc.cnot(0, 1)\n  return qc\n'''"}
{"problem": "QPC002_B3", "user": "AB8B7D7A03764", "submission_order": 2, "result": "AC", "execution_time": "1547 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.cx(0, 1)\n  qc.cx(1, 0)\n  qc.cx(0, 1)\n  return qc\n'''"}
{"problem": "QPC002_B3", "user": "AB97BA0DEA674", "submission_order": 1, "result": "AC", "execution_time": "1748 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AC42E334B86FB", "submission_order": 1, "result": "AC", "execution_time": "1642 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AC44705E31AAE", "submission_order": 1, "result": "WA", "execution_time": "1789 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AC44705E31AAE", "submission_order": 2, "result": "AC", "execution_time": "1770 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.barrier()\n    qc.cx(1,0)\n    qc.barrier()\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ACACA7D2B6FE4", "submission_order": 1, "result": "RE", "execution_time": "1025 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cnot(0,1)\n    qc.cnot(1,0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ACACA7D2B6FE4", "submission_order": 2, "result": "RE", "execution_time": "1120 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cnot(0,1)\n    qc.cnot(1,0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ACACA7D2B6FE4", "submission_order": 3, "result": "RE", "execution_time": "1343 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cnot(1,0)\n    qc.cnot(0,1)\n    qc.cnot(1,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ACACA7D2B6FE4", "submission_order": 4, "result": "RE", "execution_time": "1451 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cnot(1,0)\n    qc.cnot(0,1)\n    qc.cnot(1,0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ACACA7D2B6FE4", "submission_order": 5, "result": "UGE", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    #qc.cnot(1,0)\n    #qc.cnot(0,1)\n    #qc.cnot(1,0)\n    qc.swap(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ACACA7D2B6FE4", "submission_order": 6, "result": "AC", "execution_time": "1566 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1,0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    #qc.swap(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ACC0C92D311D1", "submission_order": 1, "result": "AC", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ACCCD7061140C", "submission_order": 1, "result": "AC", "execution_time": "1531 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AD35F567FAEFD", "submission_order": 1, "result": "RE", "execution_time": "1184 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    from qiskit.circuit.library import RZGate\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.cx(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AD35F567FAEFD", "submission_order": 2, "result": "RE", "execution_time": "1061 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    from qiskit.circuit.library import RZGate\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n'''"}
{"problem": "QPC002_B3", "user": "AD35F567FAEFD", "submission_order": 3, "result": "WA", "execution_time": "1095 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    from qiskit.circuit.library import RZGate\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AD35F567FAEFD", "submission_order": 4, "result": "AC", "execution_time": "1628 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    from qiskit.circuit.library import RZGate\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AD4A9AB723BC9", "submission_order": 1, "result": "RE", "execution_time": "1107 ms", "memory": "148 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AD4A9AB723BC9", "submission_order": 2, "result": "AC", "execution_time": "1691 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AD50302A77CDE", "submission_order": 1, "result": "AC", "execution_time": "2059 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AD7AFA652DD34", "submission_order": 1, "result": "AC", "execution_time": "2000 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AD810C2834C02", "submission_order": 1, "result": "AC", "execution_time": "2061 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ADDAB371DDA9E", "submission_order": 1, "result": "AC", "execution_time": "1381 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ADE502419F0BE", "submission_order": 1, "result": "WA", "execution_time": "1856 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ADE502419F0BE", "submission_order": 2, "result": "WA", "execution_time": "1114 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ADE502419F0BE", "submission_order": 3, "result": "AC", "execution_time": "1561 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "ADEA4EA54023B", "submission_order": 1, "result": "AC", "execution_time": "1658 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AE25E6F9B983F", "submission_order": 1, "result": "AC", "execution_time": "1725 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AE33DD58047A9", "submission_order": 1, "result": "AC", "execution_time": "1598 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AE347C8389341", "submission_order": 1, "result": "AC", "execution_time": "1831 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AE3CD58A627AA", "submission_order": 1, "result": "AC", "execution_time": "1587 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x([0,1])\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    qc.x([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AE3F2A44BB0CA", "submission_order": 1, "result": "AC", "execution_time": "1412 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AE7A5FDC98229", "submission_order": 1, "result": "UGE", "execution_time": "1135 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    matrix = [ [1, 0, 0, 0]\n             , [0, 0, 1, 0]\n             , [0, 1, 0, 0]\n             , [0, 0, 0, 1]]\n    qc.unitary(matrix, [0, 1])\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AE7A5FDC98229", "submission_order": 2, "result": "AC", "execution_time": "1546 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AEC00DE1089BF", "submission_order": 1, "result": "AC", "execution_time": "1941 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B3", "user": "AEC732C6D2C24", "submission_order": 1, "result": "UGE", "execution_time": "1093 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AECF4CE84386A", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CNOT, SwapGate\n \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1) \n    qc.append(SwapGate(), [0, 1])\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AECF4CE84386A", "submission_order": 2, "result": "WA", "execution_time": "1094 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(0) \n    qc.cx(0, 1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AECF4CE84386A", "submission_order": 3, "result": "UGE", "execution_time": "1538 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.initialize([1, 0, 0, 0], [0, 1])\n    qc.h(0) \n    qc.cx(0, 1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AECF4CE84386A", "submission_order": 4, "result": "WA", "execution_time": "1585 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.initialize([1, 0, 0, 0], [0, 1])\n    qc.h(0) \n    qc.cx(0, 1)\n    qc.h(0)\n\n    return qc.decompose(reps=5)\n'''"}
{"problem": "QPC002_B3", "user": "AEFCD30078043", "submission_order": 1, "result": "AC", "execution_time": "1564 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AEFD19F20B404", "submission_order": 1, "result": "AC", "execution_time": "1409 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AF1B4906999F2", "submission_order": 1, "result": "AC", "execution_time": "1519 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AF35342E922EB", "submission_order": 1, "result": "AC", "execution_time": "1447 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AF648B19AA679", "submission_order": 1, "result": "AC", "execution_time": "1451 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # SWAP operation using three CNOT gates\n    qc.cx(0, 1)  # CNOT with qubit 0 as control and qubit 1 as target\n    qc.cx(1, 0)  # CNOT with qubit 1 as control and qubit 0 as target\n    qc.cx(0, 1)  # CNOT with qubit 0 as control and qubit 1 as target\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AF979784408CC", "submission_order": 1, "result": "AC", "execution_time": "1601 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AF9F3AB439203", "submission_order": 1, "result": "AC", "execution_time": "1729 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC002_B3", "user": "AFBA6472700F6", "submission_order": 1, "result": "AC", "execution_time": "1581 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A0127ABFD513B", "submission_order": 1, "result": "RE", "execution_time": "2284 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for k in range(i):\n            lam = np.pi * 2.0 ** (k - i)\n            qc.cu(0, 0, lam, 0)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A0127ABFD513B", "submission_order": 2, "result": "WA", "execution_time": "1487 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for k in range(i):\n            lam = np.pi * 2.0 ** (k - i)\n            qc.cu(0, 0, lam, 0, k, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A0127ABFD513B", "submission_order": 3, "result": "DLE", "execution_time": "1110 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for k in range(i):\n            lam = np.pi * 2.0 ** (k - i)\n            qc.cu(0, 0, lam, 0, k, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A0127ABFD513B", "submission_order": 4, "result": "DLE", "execution_time": "1181 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for k in range(i):\n            lam = np.pi * 2.0 ** (k - i)\n            qc.cp(lam, i, k)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A06E075390B90", "submission_order": 1, "result": "WA", "execution_time": "1106 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        theta = 2 * np.pi\n        for j in range(i+1, n):\n            qc.cz(j, i)\n            theta /= 2\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A06E075390B90", "submission_order": 2, "result": "RE", "execution_time": "1098 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(-1, -n, -1):\n        qc.h(i)\n        theta = 2 * np.pi\n        for j in range(i+1, n):\n            qc.cz(j, i)\n            theta /= 2\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A06E075390B90", "submission_order": 3, "result": "RE", "execution_time": "1060 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(-1, -n, -1):\n        qc.h(i)\n        theta = 2 * np.pi\n        for j in range(i+1, n):\n            qc.cz(j, i)\n            theta /= 2\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A06E075390B90", "submission_order": 4, "result": "WA", "execution_time": "1065 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        theta = 2 * np.pi\n        for j in range(i+1, n):\n            qc.cz(j, i)\n            theta /= 2\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A06E075390B90", "submission_order": 5, "result": "WA", "execution_time": "1806 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        theta = 2 * np.pi\n        for j in range(i+1, n):\n            qc.crz(theta, j, i)\n            theta /= 2\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A06E075390B90", "submission_order": 6, "result": "WA", "execution_time": "1056 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        theta = 2 * np.pi\n        for j in range(i+1, n):\n            qc.crz(theta, j, i)\n            theta /= 2\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A0C0DAFC98946", "submission_order": 1, "result": "WA", "execution_time": "1168 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate,CU1Gate\nimport math\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(2*math.pi / 2**j,j,i)\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC002_B4", "user": "A0C0DAFC98946", "submission_order": 2, "result": "WA", "execution_time": "1247 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate,CU1Gate\nimport math\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(math.pi / 2**(j-i),j,i)\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC002_B4", "user": "A0C0DAFC98946", "submission_order": 3, "result": "WA", "execution_time": "1216 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate,CU1Gate\nimport math\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-1-i)\n        for j in range(i+1,n):\n            qc.cp(math.pi / 2**(j-i),n-1-j,n-1-i)\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC002_B4", "user": "A0C0DAFC98946", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate,CU1Gate\nimport math\nfrom qiskit.quantum_info import Statevector\n \n# def solve(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     for i in range(n):\n#         qc.h(n-1-i)\n#         for j in range(i+1,n):\n#             qc.cp(math.pi / 2**(j-i),n-1-j,n-1-i)\n#     return qc\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(math.pi / 2**(j-i),j,i)\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC002_B4", "user": "A0C0DAFC98946", "submission_order": 5, "result": "WA", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate\nimport math\n \n# def solve(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     for i in range(n):\n#         qc.h(n-1-i)\n#         for j in range(i+1,n):\n#             qc.cp(math.pi / 2**(j-i),n-1-j,n-1-i)\n#     return qc\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(math.pi / 2**(j-i),j,i)\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC002_B4", "user": "A0C0DAFC98946", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate,CU1Gate\nimport math\nfrom qiskit.quantum_info import Statevector\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-1-i)\n        for j in range(i+1,n):\n            qc.cp(math.pi / 2**(j-i),n-1-j,n-1-i)\n    for i in range(n//2):\n        qc.swap(i,n-1-i)\n    return qc\n# def solve(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     qc.x(0)\n#     for i in range(n):\n#         qc.h(i)\n#         for j in range(i+1,n):\n#             qc.cp(math.pi / 2**(j-i),j,i)\n#     return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n# if __name__ == \"__main__\":\n#     qc = solve(4)\n#     qc.draw(output=\"mpl\",filename=\"img.png\")\n\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B4", "user": "A0C0DAFC98946", "submission_order": 7, "result": "AC", "execution_time": "1929 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate,CU1Gate\nimport math\n#from qiskit.quantum_info import Statevector\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-1-i)\n        for j in range(i+1,n):\n            qc.cp(math.pi / 2**(j-i),n-1-j,n-1-i)\n    for i in range(n//2):\n        qc.swap(i,n-1-i)\n    return qc\n# def solve(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     qc.x(0)\n#     for i in range(n):\n#         qc.h(i)\n#         for j in range(i+1,n):\n#             qc.cp(math.pi / 2**(j-i),j,i)\n#     return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n# if __name__ == \"__main__\":\n#     qc = solve(4)\n#     qc.draw(output=\"mpl\",filename=\"img.png\")\n\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B4", "user": "A0CEC48818464", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(QFT(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A12BFC168C37D", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\nfor i in range(n):\n        qc.h(i)\n\n    # Controlled phase gates\n    for i in range(n-1):\n        for j in range(i+1, n):\n            angle = pi / (2**(j-i))\n            qc.cu1(angle, j, i)\n\n    # Swap gates (optimized)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A12BFC168C37D", "submission_order": 2, "result": "RE", "execution_time": "1211 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    # Controlled phase gates\n    for i in range(n-1):\n      for j in range(i+1, n):\n        angle = pi / (2**(j-i))\n        qc.cu1(angle, j, i)\n\n    # Swap gates (optimized)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A12BFC168C37D", "submission_order": 3, "result": "WA", "execution_time": "1083 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        # Apply Hadamard gate to qubit i\n        qc.h(i)\n        \n        # Apply controlled-phase gates\n        for j in range(i + 1, n):\n            # Apply the controlled phase gate with angle π / 2^(j-i)\n            qc.cp(np.pi / (2 ** (j - i)), j, i)\n    \n    # Swap qubits to get the correct order\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)  # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A12CEBD9B4936", "submission_order": 1, "result": "WA", "execution_time": "1340 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.p(2 * pi / 2 ** (i + 1), n - 1 - i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A12CEBD9B4936", "submission_order": 2, "result": "AC", "execution_time": "1497 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n)[::-1]:\n        qc.h(i)\n        for j in range(1, i + 1):\n            qc.cp(pi / 2 ** j, i - j, i)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A16FC14196AFD", "submission_order": 1, "result": "RE", "execution_time": "1263 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cp(pi/2**(n-range(n)), range(n), n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A16FC14196AFD", "submission_order": 2, "result": "RE", "execution_time": "1120 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n   # Apply Hadamard gate to the most significant qubit\n    qc.h(n-1)\n    \n    # Apply controlled rotations to all qubits\n    for i in range(n-1, 0, -1):\n        for j in range(n-i-1):\n            qc.cu1(np.pi/2**(j+1), i-j-1, i)\n        qc.h(i)\n    \n    # Apply swap gates to reverse the order of the qubits\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A16FC14196AFD", "submission_order": 3, "result": "RE", "execution_time": "1058 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\ndef qft_rotations(circuit, n):\n    if n == 0: # Exit function if circuit is empty\n        return circuit\n    n -= 1 # Indexes start from 0\n    circuit.h(n) # Apply the H-gate to the most significant qubit\n    for qubit in range(n):\n        # For each less significant qubit, we need to do a\n        # smaller-angled controlled rotation: \n        circuit.cp(pi/2**(n-qubit), qubit, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A16FC14196AFD", "submission_order": 4, "result": "RE", "execution_time": "1586 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n# Apply Hadamard gate and controlled phase gates\n    for i in range(n):\n        # Apply Hadamard gate to the i-th qubit\n        qc.h(i)\n        \n        # Apply controlled phase gates\n        for j in range(i + 1, n):\n            angle = pi / (2 ** (j - i))\n            qc.cp(angle, j, i)\n    \n    # Reverse the order of the qubits\n    qc.swap(0, n - 1)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A16FC14196AFD", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n# Apply Hadamard gate and controlled phase gates\nimport numpy as np\n    for i in range(n):\n        # Apply Hadamard gate to the i-th qubit\n        qc.h(i)\n        \n        # Apply controlled phase gates\n        for j in range(i + 1, n):\n            angle = np.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)\n    \n    # Reverse the order of the qubits\n    qc.swap(0, n - 1)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1861F8FCEE64", "submission_order": 1, "result": "RE", "execution_time": "1076 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1, n):\n            qc.cp(np.pi / (2**(k-j)), k, j)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1861F8FCEE64", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n for j in range(n):\n        qc.h(j)\n        for k in range(j+1, n):\n            qc.cp(np.pi / (2 ** (k - j)), k, j)\n    \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1861F8FCEE64", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n  for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(np.pi / (2 ** (k - j)), k, j)\n    \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 1, "result": "RE", "execution_time": "1142 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            circuit.cp(pi/2**(q-i), i, q)\n\n        rotations(q)\n\n    roations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 2, "result": "RE", "execution_time": "1092 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            circuit.cp(pi/2**(q-i), i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 3, "result": "DLE", "execution_time": "1179 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            qc.cp(pi/2**(q-i), i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import p\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            if phase > 0.0001:\n                qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import p\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            if phase > 0.0001:\n                qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import p\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            if phase > 0.1:\n                qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 7, "result": "WA", "execution_time": "1907 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            if phase > 0.1:\n                qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 8, "result": "DLE", "execution_time": "1077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            if phase > 0.001:\n                qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 9, "result": "DLE", "execution_time": "1065 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            if phase > 0.01:\n                qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 10, "result": "DLE", "execution_time": "2061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            if phase > 0.05:\n                qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 11, "result": "WA", "execution_time": "1132 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            if phase > 0.1:\n                qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 12, "result": "WA", "execution_time": "1111 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    # for i in range(n//2):\n    #     qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C501207D2B8", "submission_order": 13, "result": "DLE", "execution_time": "1072 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def rotations(q):\n        if q == 0:\n            return \n        q -= 1\n        qc.h(q)\n        for i in range(q):\n            phase = pi/2**(q-i)\n            qc.cp(phase, i, q)\n\n        rotations(q)\n\n    rotations(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C7A931D8470", "submission_order": 1, "result": "RE", "execution_time": "1941 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cp(0.5*math.pi,0,1)\n    qc.x(1)\n    qc.cp(0.5*math.pi,0,1)\n    qc.cp(math.pi,1,0)\n    qc.x(0)\n    qc.cp(math.pi,1,0)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C7A931D8470", "submission_order": 2, "result": "WA", "execution_time": "1189 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(2*math.pi/(1<<(j-i+1)),j,i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A1C7A931D8470", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import QFTGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.QFTGate(n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A2160C90003CA", "submission_order": 1, "result": "WA", "execution_time": "1304 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        qc.h(j)\n    for k in range(j+1,n):\n        angle=np.pi/2**(k-j)\n        qc.rz(angle,k)\n    for i in range(n//2):\n        qc.swap(i,n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A23E9F8BDD14F", "submission_order": 1, "result": "AC", "execution_time": "2097 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i):\n            qc.cp(math.pi/(2**(j+1)), i-j-1, i)\n\n    for i in range(int(n/2)):\n        qc.swap(i,n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A251BE5CA6E84", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Operator\nfrom qiskit.circuit.library import CU1Gate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(j-1, -1, -1):\n            theta = np.pi/float(2**(j-m))\n            cu1 = Operator(CU1Gate(theta=theta).to_matrix())\n            qc.unitary(cu1, [j, i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A251BE5CA6E84", "submission_order": 2, "result": "RE", "execution_time": "1077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(j-1, -1, -1):\n            theta = np.pi/float(2**(j-m))\n            qc.cu1(j, i, theta)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A251BE5CA6E84", "submission_order": 3, "result": "RE", "execution_time": "1415 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(j-1, -1, -1):\n            theta = np.pi/float(2**(j-i))\n            qc.cu1(j, i, theta)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A251BE5CA6E84", "submission_order": 4, "result": "RE", "execution_time": "1061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(j-1, -1, -1):\n            theta = np.pi/float(2**(j-i))\n            qc.cu1(theta, j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A251BE5CA6E84", "submission_order": 5, "result": "RE", "execution_time": "1097 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(j-1, -1, -1):\n            theta = np.pi/float(2**(j-i))\n            qc.cu1(theta,qc[j], qc[i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A26A8DE2CCF4B", "submission_order": 1, "result": "WA", "execution_time": "1111 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            theta = -2*math.pi/(2**(j+1-i))\n            qc.crz(theta,i,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A26A8DE2CCF4B", "submission_order": 2, "result": "WA", "execution_time": "1103 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            theta = -2*math.pi/(2**(j-i))\n            qc.crz(theta,i,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A2B5C7EDDD3AF", "submission_order": 1, "result": "WA", "execution_time": "2612 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(2*math.pi/2**(j-i),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A2B5C7EDDD3AF", "submission_order": 2, "result": "WA", "execution_time": "1837 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(2*math.pi/2**(j-i+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A2B5C7EDDD3AF", "submission_order": 3, "result": "AC", "execution_time": "2129 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A2E8E9B587C41", "submission_order": 1, "result": "RE", "execution_time": "1140 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.QFTgate(n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A30FFA9D0548B", "submission_order": 1, "result": "WA", "execution_time": "1323 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    #Applying QFT\n    for i in range(n):\n        qc.h(i)\n        #Apply controlled phase gate\n        for j in range(i+1,n):\n            qc.cp(math.pi/2**(j-i),j,i)\n    \n    #Swap qubits to reverse the order\n    for i in range(n//2):\n        qc.swap(i,n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A30FFA9D0548B", "submission_order": 2, "result": "WA", "execution_time": "1089 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    #Applying QFT\n    for i in range(n):\n        qc.h(n-i-1)\n        #Apply controlled phase gate\n        for j in range(1,n-1):\n            qc.cp(math.pi/2**j,n-i-j-1,n-i-1)\n    \n    #Swap qubits to reverse the order\n    for i in range(n//2):\n        qc.swap(i,n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A30FFA9D0548B", "submission_order": 3, "result": "AC", "execution_time": "1786 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    #Applying QFT\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    \n    #Swap qubits to reverse the order\n    for i in range(n//2):\n        qc.swap(i,n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 1, "result": "RE", "execution_time": "1441 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for k in range(i+1, n):\n            qc.cp(pi/2**(k-i), k, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 2, "result": "WA", "execution_time": "1294 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for k in range(i+1, n):\n            qc.cp(pi/2**(k-i), k, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import p\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for k in range(i+1, n):\n            qc.cp(pi/2**(k-i), k, i)\n    for i in range(n//2):\n        qc.swap(j, n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import p\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1, 0, -1):\n        qc.h(i)\n        for k in range(i+1, n):\n            qc.cp(pi/2**(k-i), k, i)\n\n    for j in range(n//2):\n        qc.swap(j, n-j-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 5, "result": "WA", "execution_time": "1087 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1, 0, -1):\n        qc.h(i)\n        for k in range(i+1, n):\n            qc.cp(pi/2**(k-i), k, i)\n\n    for j in range(n//2):\n        qc.swap(j, n-j-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 6, "result": "WA", "execution_time": "1066 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**(k+1)), k, i)\n\n    for j in range(n//2):\n        qc.swap(j, n-j-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 7, "result": "WA", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**(k+1)), k, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 8, "result": "WA", "execution_time": "1232 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**(k+1)), k, i)\n\n    for i in range(floor(n/2)):\n        qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 9, "result": "WA", "execution_time": "1169 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 2\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**r_count), k, i)\n            r_count+=1\n\n    for i in range(floor(n/2)):\n        qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 10, "result": "WA", "execution_time": "1303 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 2\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**r_count), k, i)\n            r_count+=1\n\n    # for i in range(floor(n/2)):\n    #     qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 11, "result": "WA", "execution_time": "1400 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 2\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**r_count), i, k)\n            r_count+=1\n\n    for i in range(floor(n/2)):\n        qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 12, "result": "WA", "execution_time": "1277 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 2\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**r_count), i, k)\n            r_count+=1\n\n    # for i in range(floor(n/2)):\n    #     qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 13, "result": "WA", "execution_time": "1176 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 2\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**r_count), i, k)\n            r_count+=1\n    if n > 1:\n        qc.h(n-1)\n    for i in range(floor(n/2)):\n        qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 14, "result": "WA", "execution_time": "1087 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 2\n        for k in range(i+1, n):\n            qc.cp(2*pi/(2**r_count), i, k)\n            r_count+=1\n    if n > 1:\n        qc.h(n-1)\n    # for i in range(floor(n/2)):\n    #     qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 15, "result": "WA", "execution_time": "1241 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 1\n        for k in range(i+1, n):\n            qc.cp(pi/(2**r_count), i, k)\n            r_count+=1\n\n    for i in range(floor(n/2)):\n        qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 16, "result": "WA", "execution_time": "1123 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, floor\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 1\n        for k in range(i+1, n):\n            qc.cp(pi/(2**r_count), i, k)\n            r_count+=1\n\n    # for i in range(floor(n/2)):\n    #     qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 17, "result": "WA", "execution_time": "1421 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import floor\nfrom numpy import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        r_count = 1\n        for k in range(i+1, n):\n            qc.cp(pi/(2**r_count), i, k)\n            r_count+=1\n\n    for i in range(floor(n/2)):\n        qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 18, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import floor\nfrom numpy import p\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        r_count = 1\n        for k in range(i-1, -1, -1):\n            qc.cp(pi/(2**r_count), k, i)\n            r_count+=1\n\n    for i in range(floor(n/2)):\n        qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A313CE010348F", "submission_order": 19, "result": "AC", "execution_time": "1778 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import floor\nfrom numpy import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        r_count = 1\n        for k in range(i-1, -1, -1):\n            qc.cp(pi/(2**r_count), k, i)\n            r_count+=1\n\n    for i in range(floor(n/2)):\n        qc.swap(i , n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 1, "result": "WA", "execution_time": "1259 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n        for j in range(i+1, n):\n            qc.cp(np.pi / (2 ** (j - i)), j, i)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 2, "result": "WA", "execution_time": "1121 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n        for j in range(i+1, n):\n            qc.cp(2*np.pi / (2 ** (j - i)), j, i)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 3, "result": "WA", "execution_time": "1136 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n        for j in range(i+1, n):\n            qc.cp(2*np.pi / (2 ** (j - i)), j, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 4, "result": "WA", "execution_time": "1554 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n        for j in range(i+1, n):\n            qc.cp(np.pi / (2 ** (j - i)), j, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 5, "result": "RE", "execution_time": "1333 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(qlib.PhaseGate(np.pi/2).control(n - 1), range(n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            if not (L >> j) & 1:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 6, "result": "WA", "execution_time": "1269 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        for j in range(i + 1, n):\n            qc.x(j)\n        qc.x(i)\n        if i == n - 1:\n            qc.z(i)\n        else:\n            qc.append(qlib.PhaseGate(np.pi/2).control(n - 1), range(n))\n        qc.x(i)\n        for j in range(i + 1, n):\n            qc.x(j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 7, "result": "WA", "execution_time": "1220 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n        for j in range(i+1, n):\n            qc.cp(np.pi / (2 ** (j - i)), j, i)\n    \n    for i in range(n // 2):\n        qc.cx(i, n - i - 1)\n        qc.cx(i, n - i - 1)\n        qc.cx(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 8, "result": "WA", "execution_time": "1053 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n - 1, -1, -1):\n        for j in range(n - 1, i, -1):\n            qc.cp(np.pi / (2 ** (j - i)), j, i)\n        \n        qc.h(i)  # Hadamardゲートも逆順で適\n    \n    for i in range(n // 2):\n        qc.cx(i, n - i - 1)\n        qc.cx(i, n - i - 1)\n        qc.cx(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A35A41FC9B255", "submission_order": 9, "result": "AC", "execution_time": "2061 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n - 1, -1, -1):\n        for j in range(n - 1, i, -1):\n            qc.cp(np.pi / (2 ** (j - i)), j, i)\n        \n        qc.h(i)  # Hadamardゲートも逆順で適\n    \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A36A2FCD3D29D", "submission_order": 1, "result": "RE", "execution_time": "1183 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    #Applying QFT\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    \n    #Swap qubits to reverse the order\n    for i in range(n//2):\n        qc.swap(i,n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A36A2FCD3D29D", "submission_order": 2, "result": "AC", "execution_time": "1840 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    #Applying QFT\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    \n    #Swap qubits to reverse the order\n    for i in range(n//2):\n        qc.swap(i,n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3B97FDE3F903", "submission_order": 1, "result": "RE", "execution_time": "1917 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef rk(qc, qubit1, qubit2, k):\n    qc.cp(2 * 3.14 / 2**k, qubit1, qubit2)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(2, 2 + n - i - 1):\n            rk(qc, i, i + j - 1, j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3B97FDE3F903", "submission_order": 2, "result": "WA", "execution_time": "1184 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef rk(qc, qubit1, qubit2, k):\n    qc.cp(2 * pi / 2**k, qubit1, qubit2)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.x(1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            rk(qc, i, j, j - i + 1)\n        qc.barrier()\n            # print(i, j, j - i + 1)\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3B97FDE3F903", "submission_order": 3, "result": "WA", "execution_time": "1502 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef rk(qc, qubit1, qubit2, k):\n    qc.cp(2 * pi / 2**k, qubit1, qubit2)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.x(1)\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in range(i + 1, n):\n            rk(qc, i, j, j - i + 1)\n        qc.barrier()\n            # print(i, j, j - i + 1)\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3B97FDE3F903", "submission_order": 4, "result": "AC", "execution_time": "1765 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in reversed(range(0, j)):\n            lam = pi * (2.0 ** (k - j))\n            qc.cp(lam, j, k)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3E9FC25084A2", "submission_order": 1, "result": "RE", "execution_time": "1157 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    t = pi/(1<<n)\n    for i in range(n):\n        cp.p(t*(1<<i),i)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3E9FC25084A2", "submission_order": 2, "result": "WA", "execution_time": "1321 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    t = pi/(1<<n)\n    for i in range(n):\n        qc.p(t*(1<<i),i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3E9FC25084A2", "submission_order": 3, "result": "WA", "execution_time": "1403 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    t = pi/(1<<n)\n    for i in range(n):\n        qc.p(t,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = qc.compose(QFT(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    data_qubits = n\n    for i in range(data_qubits):\n        qc.h(qr_data[-1-i])\n        for j in range(i+1,data_qubits):\n            qc.cp(2 * math.pi / 2**(j+1-i), qr_data[-1-j], qr_data[-1-i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 3, "result": "RE", "execution_time": "1176 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    data_qubits = n\n    for i in range(data_qubits):\n        qc.h(qr_data[-1-i])\n        for j in range(i+1,data_qubits):\n            qc.cp(2 * math.pi / 2**(j+1-i), qr_data[-1-j], qr_data[-1-i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 4, "result": "RE", "execution_time": "1133 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    data_qubits = n\n    qr_data =qc.qubits\n    for i in range(data_qubits):\n        qc.h(qr_data[-1-i])\n        for j in range(i+1,data_qubits):\n            qc.cp(2 * math.pi / 2**(j+1-i), qr_data[-1-j], qr_data[-1-i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 5, "result": "WA", "execution_time": "1377 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    data_qubits = n\n    qr_data =qc.qubits\n    for i in range(data_qubits):\n        qc.h(qr_data[-1-i])\n        for j in range(i+1,data_qubits):\n            qc.cp(2 * math.pi / 2**(j+1-i), qr_data[-1-j], qr_data[-1-i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 6, "result": "WA", "execution_time": "1155 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    data_qubits = n\n    qr_data =qc.qubits\n    for i in range(data_qubits-1,-1,-1):\n\n        qc.h(qr_data[-1-i])\n        for j in range(i+1,data_qubits):\n            qc.cp(2 * math.pi / 2**(j+1-i), qr_data[-1-j], qr_data[-1-i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 7, "result": "WA", "execution_time": "1441 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(2,i+2):\n            qc.cp(2 * math.pi / 2**j, i-j+1, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 8, "result": "WA", "execution_time": "1292 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        i=-i-1\n        qc.h(i)\n        for j in range(2,i+2):\n            j=-j-1\n            qc.cp(2 * math.pi / 2**j, i-j+1, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 9, "result": "RE", "execution_time": "1092 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        i2=n-i-1\n        qc.h(i2)\n        for j in range(2,i+2):\n            j2=n-j\n            # print(i,j,i2,j2)\n            qc.cp(2 * math.pi / 2**j, i2-j2+1, i2)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 10, "result": "WA", "execution_time": "1102 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(2,i+2):\n            qc.cp(2 * math.pi / 2**j, i-(j-1), i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 11, "result": "WA", "execution_time": "1211 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(2,i+2):\n            qc.cp(2 * math.pi / 2**j, i-(j-1), i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 12, "result": "WA", "execution_time": "1223 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # QFTのコア部分を実装\n    for i in range(n):\n        qc.h(i)  # Hadamard gate on qubit i\n        \n        for j in range(i + 1, n):\n            # Controlled phase rotation with angle π/(2^(j-i))\n            angle = math.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)\n    \n    # ビットの順序を反転\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 13, "result": "WA", "execution_time": "1116 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # QFTのコア部分を実装\n    for i in range(n):\n        qc.h(i)  # Hadamard gate on qubit i\n        \n        for j in range(i + 1, n):\n            # Controlled phase rotation with angle π/(2^(j-i))\n            angle = math.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 14, "result": "WA", "execution_time": "1414 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # QFTのコア部分を実装\n    for i in range(n):\n        i2=n-i-1\n        qc.h(i2)  # Hadamard gate on qubit i\n        \n        for j in range(i + 1, n):\n            j2=n-j-1\n            # Controlled phase rotation with angle π/(2^(j-i))\n            angle = math.pi / (2 ** (j - i))\n            qc.cp(angle, j2, i2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A3EB64EFCB732", "submission_order": 15, "result": "WA", "execution_time": "1131 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # QFTのコア部分を実装\n    for i in range(n):\n        i2=n-i-1\n        qc.h(i)  # Hadamard gate on qubit i\n        \n        for j in range(i + 1, n):\n            j2=n-j-1\n            # Controlled phase rotation with angle π/(2^(j-i))\n            angle = math.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A42235C3B81D0", "submission_order": 1, "result": "RE", "execution_time": "1666 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i = 0\n    while n-1-i>i:\n        qc.swap(i,n-1-i)\n        i += 1\n    qc.append(QFTGate(n),range(n))\n    i = 0\n    while n-1-i>i:\n        qc.swap(i,n-1-i)\n        i += 1\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A42235C3B81D0", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFTGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    i = 0\n    while n-1-i>i:\n        qc.swap(i,n-1-i)\n        i += 1\n    qc.append(QFTGate(n),range(n))\n    i = 0\n    while n-1-i>i:\n        qc.swap(i,n-1-i)\n        i += 1\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A42235C3B81D0", "submission_order": 3, "result": "TLE", "execution_time": "3000 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi/(1<<(i-j)),j,i)\n    i = 0\n    while i<n-i-1:\n        qc.swap(i,n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A42235C3B81D0", "submission_order": 4, "result": "AC", "execution_time": "2057 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi/(1<<(i-j)),j,i)\n    i = 0\n    while i<n-i-1:\n        qc.swap(i,n-i-1)\n        i += 1\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 1, "result": "WA", "execution_time": "1336 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n-1):\n        for j in range(i+1, n):\n            qc.cp(2*math.pi/2**(1+j-i), j, i)\n        qc.h(i+1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 2, "result": "RE", "execution_time": "1068 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        for k in range(j):\n            qc.cu1(2 * np.pi / 2**(j - k), k, j)\n        qc.h(j)\n    return qc\n    \"\"\"\n    qc.h(0)\n    for i in range(n-1):\n        for j in range(i+1, n):\n            qc.cp(2*math.pi/2**(1+j-i), j, i)\n        qc.h(i+1)\n    return qc\n    \"\"\"\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 3, "result": "RE", "execution_time": "1214 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        for k in range(j):\n            qc.cp(2 * np.pi / 2**(j - k), k, j)\n        qc.h(j)\n    return qc\n    \"\"\"\n    qc.h(0)\n    for i in range(n-1):\n        for j in range(i+1, n):\n            qc.cp(2*math.pi/2**(1+j-i), j, i)\n        qc.h(i+1)\n    return qc\n    \"\"\"\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 4, "result": "WA", "execution_time": "1157 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        for k in range(j):\n            qc.cp(2 * math.pi / 2**(j - k), k, j)\n        qc.h(j)\n    return qc\n    \"\"\"\n    qc.h(0)\n    for i in range(n-1):\n        for j in range(i+1, n):\n            qc.cp(2*math.pi/2**(1+j-i), j, i)\n        qc.h(i+1)\n    return qc\n    \"\"\"\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 5, "result": "RE", "execution_time": "1807 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi / float(2**(k-j)), j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 6, "result": "WA", "execution_time": "1176 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi / float(2**(j-i)), j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 7, "result": "WA", "execution_time": "1584 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi / float(2**(j-i)), j, i)\n        qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 8, "result": "RE", "execution_time": "1062 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cu1(math.pi / float(2**(j-i)), j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 9, "result": "RE", "execution_time": "1066 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi / float(2**(j-i)), j, i)\n    for i in range(n//2):\n        qc.swap(i, n-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 10, "result": "WA", "execution_time": "1164 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi / float(2**(j-i)), j, i)\n    #for i in range(n//2):\n    #    qc.swap(i, n-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 11, "result": "WA", "execution_time": "1558 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi / float(2**(j-i)), j, i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4B2B997E1120", "submission_order": 12, "result": "AC", "execution_time": "1566 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi / float(2**(j-i)), j, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4D9E0692F1D6", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_rotations(circuit, n):\n    \"\"\"Performs qft on the first n qubits in circuit (without swaps)\"\"\"\n        if n == 0:\n            return circuit\n        n -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(pi/2**(n-qubit), qubit, n)\n    # At the end of our function, we call the same function again on\n    # the next qubits (we reduced n by one earlier in the function)\n        qft_rotations(circuit, n)\n\n    def swap_registers(circuit, n):\n        for qubit in range(n//2):\n            circuit.swap(qubit, n-qubit-1)\n        return circuit\n\n    def qft(circuit, n):\n        \"\"\"QFT on the first n qubits in circuit\"\"\"\n        qft_rotations(circuit, n)\n        swap_registers(circuit, n)\n        return circuit\n\n    qft(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4D9E0692F1D6", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_rotations(circuit, n):\n    \"\"\"Performs qft on the first n qubits in circuit (without swaps)\"\"\"\n        if n == 0:\n            return circuit\n        n -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(pi/2**(n-qubit), qubit, n)\n    # At the end of our function, we call the same function again on\n    # the next qubits (we reduced n by one earlier in the function)\n        qft_rotations(circuit, n)\n\n    def swap_registers(circuit, n):\n        for qubit in range(n//2):\n            circuit.swap(qubit, n-qubit-1)\n        return circuit\n\n    def qft(circuit, n):\n        \"\"\"QFT on the first n qubits in circuit\"\"\"\n        qft_rotations(circuit, n)\n        swap_registers(circuit, n)\n        return circuit\n\n    qft(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4D9E0692F1D6", "submission_order": 3, "result": "RE", "execution_time": "1197 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_rotations(circuit, n):\n        \"\"\"Performs qft on the first n qubits in circuit (without swaps)\"\"\"\n        if n == 0:\n            return circuit\n        n -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(pi/2**(n-qubit), qubit, n)\n        # At the end of our function, we call the same function again on\n        # the next qubits (we reduced n by one earlier in the function)\n        qft_rotations(circuit, n)\n\n    def swap_registers(circuit, n):\n        for qubit in range(n//2):\n            circuit.swap(qubit, n-qubit-1)\n        return circuit\n\n    def qft(circuit, n):\n        \"\"\"QFT on the first n qubits in circuit\"\"\"\n        qft_rotations(circuit, n)\n        swap_registers(circuit, n)\n        return circuit\n\n    qft(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4D9E0692F1D6", "submission_order": 4, "result": "RE", "execution_time": "1094 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_rotations(circuit, n):\n        \"\"\"Performs qft on the first n qubits in circuit (without swaps)\"\"\"\n        if n == 0:\n            return circuit\n        n -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(pi/2**(n-qubit), qubit, n)\n        # At the end of our function, we call the same function again on\n        # the next qubits (we reduced n by one earlier in the function)\n        qft_rotations(circuit, n)\n\n    def swap_registers(circuit, n):\n        for qubit in range(n//2):\n            circuit.swap(qubit, n-qubit-1)\n        return circuit\n\n    def qft(circuit, n):\n        \"\"\"QFT on the first n qubits in circuit\"\"\"\n        qft_rotations(circuit, n)\n        swap_registers(circuit, n)\n        return circuit\n\n    qft(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A4D9E0692F1D6", "submission_order": 5, "result": "RE", "execution_time": "1080 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    circuit = QuantumCircuit(n)\n    # Write your code here:\n    #\n    # We start with the most significant bit\n    #\n    for k in range(n):\n        j = n - k\n        # Add the Hadamard to qubit j-1\n        circuit.h(q[j-1])\n        #\n        # there is one conditional rotation for\n        # each qubit with lower significance\n        for i in reversed(range(j-1)):\n            circuit.cu1(2*np.pi/2**(j-i),q[i], q[j-1])\n    #\n    # Finally we need to swap qubits\n    #\n    for i in range(n//2):\n        circuit.swap(q[i], q[n-i-1])\n    return circuit\n'''"}
{"problem": "QPC002_B4", "user": "A4D9E0692F1D6", "submission_order": 6, "result": "AC", "execution_time": "2009 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    circuit = QuantumCircuit(n)\n    # Write your code here:\n    #\n    q = [i for i in range(n)]\n    # We start with the most significant bit\n    #\n    for k in range(n):\n        j = n - k\n        # Add the Hadamard to qubit j-1\n        circuit.h(q[j-1])\n        #\n        # there is one conditional rotation for\n        # each qubit with lower significance\n        for i in reversed(range(j-1)):\n            circuit.cp(2*np.pi/2**(j-i),q[i], q[j-1])\n    #\n    # Finally we need to swap qubits\n    #\n    for i in range(n//2):\n        circuit.swap(q[i], q[n-i-1])\n    return circuit\n'''"}
{"problem": "QPC002_B4", "user": "A4EFE2435FC18", "submission_order": 1, "result": "AC", "execution_time": "2254 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n\tfrom numpy import pi\n\tqc = QuantumCircuit(n)\n\tfor i in reversed(range(n)):\n\t\tqc.h(i)\n\t\tfor j in reversed(range(i)):\n\t\t\tqc.cp(pi / 2**(i-j), j, i)\n\ti, j = 0, n - 1\n\twhile i < j:\n\t\tqc.swap(i, j)\n\t\ti, j = i + 1, j - 1\n\treturn qc\n'''"}
{"problem": "QPC002_B4", "user": "A541EEE0FB94E", "submission_order": 1, "result": "RE", "execution_time": "1791 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply QFT\n    for j in range(n):\n        # Apply Hadamard gate to the j-th qubit\n        qc.h(j)\n        \n        # Apply controlled phase rotations\n        for k in range(j + 1, n):\n            qc.cp(math.pi / (2 ** (k - j)), k, j)\n    \n    # Reverse the order of the qubits\n    for j in range(n // 2):\n        qc.swap(j, n - j - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A541EEE0FB94E", "submission_order": 2, "result": "WA", "execution_time": "1984 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply QFT\n    for j in range(n):\n        # Apply Hadamard gate to the j-th qubit\n        qc.h(j)\n        \n        # Apply controlled phase rotations\n        for k in range(j + 1, n):\n            qc.cp(math.pi / (2 ** (k - j)), k, j)\n    \n    # Reverse the order of the qubits\n    for j in range(n // 2):\n        qc.swap(j, n - j - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A541EEE0FB94E", "submission_order": 3, "result": "WA", "execution_time": "1866 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates\n    for j in range(n):\n        qc.h(j)\n        \n        # Apply controlled phase rotations\n        for k in range(j + 1, n):\n            angle = math.pi / (2 ** (k - j + 1))\n            qc.cp(angle, k, j)  # Controlled phase rotation\n\n    # Reverse the order of qubits\n    for j in range(n // 2):\n        qc.swap(j, n - j - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A552062457EEC", "submission_order": 1, "result": "RE", "execution_time": "1098 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.crz(2 * math.pi / (2 ** (k - j + 1)), k, j)\n    \n    for j in range(n // 2):\n        qc.swap(j, n - j - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A552062457EEC", "submission_order": 2, "result": "RE", "execution_time": "1157 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(n - 1 - i)\n        for j in range(i + 1, n):\n            qc.crz(2 * math.pi / (2 ** (j - i + 1)), n - j - 1, n - i - 1)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A552062457EEC", "submission_order": 3, "result": "RE", "execution_time": "1503 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(n - 1 - i)\n        for j in range(i + 1, n):\n            qc.cp(2 * math.pi / (2 ** (j - i + 1)), n - j - 1, n - i - 1)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A552062457EEC", "submission_order": 4, "result": "WA", "execution_time": "1468 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.crz(2 * math.pi / (2 ** (j - i + 1)), n - j - 1, n - i - 1)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A552062457EEC", "submission_order": 5, "result": "WA", "execution_time": "1716 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(2 * math.pi / (2 ** (j - i + 1)), n - j - 1, n - i - 1)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A552062457EEC", "submission_order": 6, "result": "AC", "execution_time": "1702 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(n - i - 1)\n        for j in range(i + 1, n):\n            qc.cp(2 * math.pi / (2 ** (j - i + 1)), n - j - 1, n - i - 1)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5532907610C9", "submission_order": 1, "result": "RE", "execution_time": "1068 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(pi / (1 << (i - j)), j, i)\n\n    for i in range(n // 2):\n        j = n - i - 1\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5532907610C9", "submission_order": 2, "result": "AC", "execution_time": "1834 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(pi / (1 << (i - j)), j, i)\n\n    for i in range(n // 2):\n        j = n - i - 1\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5674CBA99F4B", "submission_order": 1, "result": "RE", "execution_time": "1076 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    n -= 1\n    qc.h(n)\n    for q in range(n):\n        qc.cp(pi/2**(n-q),q,n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5674CBA99F4B", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U1Gate, pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    n -= 1\n    qc.h(n)\n    for q in range(n):\n        qc.cp(pi/2**(n-q),q,n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5674CBA99F4B", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CPGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    n -= 1\n    qc.append(HGate(), [n])\n    for q in range(n):\n        qc.append(CPGate(math.pi/2**(n-q)), [q, n])\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5957A9EA0A81", "submission_order": 1, "result": "AC", "execution_time": "1567 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A598721E6AC87", "submission_order": 1, "result": "RE", "execution_time": "1408 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef QFT(qc):\n    n = qc.num_qubits\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    QFT(qc)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5B77FE759525", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(QFT(n),range(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5B77FE759525", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(QFT(n),range(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5B77FE759525", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi/(2**(j-i)), j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5B77FE759525", "submission_order": 4, "result": "RE", "execution_time": "1203 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi/(2**(j-i)), j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A5B77FE759525", "submission_order": 5, "result": "WA", "execution_time": "1039 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi/(2**(j-i)), j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 1, "result": "RE", "execution_time": "1554 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in reversed(range(j)):\n            qc.cp(np.pi/2**(j-k), k, j)\n        qc.barrier()\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 2, "result": "RE", "execution_time": "1068 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in reversed(range(j)):\n            qc.cp(np.pi/2**(j-k), k, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return QFT(n)\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(np.pi/2**(j-k), k, j)\n        qc.barrier()\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 5, "result": "RE", "execution_time": "1124 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(np.pi/2**(j-k), k, j)\n        qc.barrier()\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 6, "result": "RE", "execution_time": "1519 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(np.pi/2**(j-k), k, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 7, "result": "RE", "execution_time": "1290 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(np.pi/2**(j-k), k, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 8, "result": "WA", "execution_time": "1353 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(pi/2**(j-k), k, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 9, "result": "WA", "execution_time": "1255 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in reversed(range(j)):\n            qc.cp(pi/2**(j-k), k, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 10, "result": "WA", "execution_time": "1378 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(pi/2**(j-k), k, j)\n    #for i in range(n//2):\n    #    qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 11, "result": "DLE", "execution_time": "1106 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(pi/2**(j-k), k, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 12, "result": "WA", "execution_time": "1091 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(pi/2**(j-k), k, j)\n    #for i in range(n//2):\n    #    qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 13, "result": "WA", "execution_time": "1238 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in reversed(range(j)):\n            qc.cp(pi/2**(j-k), k, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 14, "result": "WA", "execution_time": "1035 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in reversed(range(j)):\n            qc.cp(pi/2**(j-k), k, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 15, "result": "WA", "execution_time": "1139 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(pi/2**(j-k), k, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 16, "result": "WA", "execution_time": "1239 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j):\n            qc.cp(pi/2**(j-k), k, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 17, "result": "WA", "execution_time": "1208 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(pi/2**(k-j), j, k)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 18, "result": "WA", "execution_time": "1115 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(pi/2**(k-j), j, k)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 19, "result": "WA", "execution_time": "1069 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(pi/2**(k-j), j, k)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 20, "result": "WA", "execution_time": "1070 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(pi/2**(k-j), j, k)\n    #for i in range(n//2):\n    #    qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 21, "result": "WA", "execution_time": "1185 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(pi/2**(k-j), j, k)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 22, "result": "WA", "execution_time": "1542 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(2*pi*(k-j)/2**n, j, k)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 23, "result": "WA", "execution_time": "1656 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(2*pi/2**(k-j+1), j, k)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6615DB6172BF", "submission_order": 24, "result": "WA", "execution_time": "1627 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(2*pi/(2**(k-j+1)), j, k)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66407DA16B6C", "submission_order": 1, "result": "WA", "execution_time": "1211 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U1Gate\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(i+1, n):\n            qc.append(U1Gate(math.pi/2**j).control(1), [n-j-1,n-i-1])\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66407DA16B6C", "submission_order": 2, "result": "WA", "execution_time": "1560 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U1Gate\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(i+1, n):\n            qc.append(U1Gate(math.pi/2**j).control(1), [n-j-1,n-i-1])\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66407DA16B6C", "submission_order": 3, "result": "AC", "execution_time": "1783 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U1Gate\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.append(U1Gate(math.pi/2**j).control(1), [n-i-j-1,n-i-1])\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6643FB7851DD", "submission_order": 1, "result": "RE", "execution_time": "1182 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = math.pi\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6643FB7851DD", "submission_order": 2, "result": "WA", "execution_time": "1146 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = math.pi\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qft = QFT(n, inverse=False)  # Inverse=False for QFT, True for QFT†\n    qc.append(qft, range(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 2, "result": "RE", "execution_time": "1728 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu1(math.pi/float(2**(k-j)),k,j)\n        qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 3, "result": "RE", "execution_time": "1037 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu1(math.pi/float(2**(k-j)),k,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 4, "result": "RE", "execution_time": "1094 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu1(3.141592/float(2**(k-j)),k,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 5, "result": "RE", "execution_time": "1355 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu1(3.141592/2**(k-j),k,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 6, "result": "WA", "execution_time": "1191 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cp(3.141592/2**(k-j),k,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 7, "result": "RE", "execution_time": "1608 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu(3.141592/2**(k-j),k,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 8, "result": "WA", "execution_time": "1085 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu(3.141592/2**(k-j),0,0,0,k,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 9, "result": "WA", "execution_time": "1377 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu(0,0,3.141592/2**(k-j),0,k,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 10, "result": "WA", "execution_time": "1163 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu(0,0,0,3.141592/2**(k-j),k,j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 11, "result": "WA", "execution_time": "1142 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-1-i)\n        for j in range(i+1,n):\n            qc.cp(2 * 3.141592 / 2**(j+1-i), n-1-j, n-1-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 12, "result": "RE", "execution_time": "1295 ms", "memory": "154 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for q in reversed(range(i)):\n            qc.cp(pi/2**(i-q),q,i)\n    for i in range(math.floor(n/2)):\n        qc.swap(i,n-(i+1))\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A66C0ADD19DBB", "submission_order": 13, "result": "AC", "execution_time": "1665 ms", "memory": "156 MiB", "code": "'''python\nimport math\nfrom numpy import pi\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for q in reversed(range(i)):\n            qc.cp(pi/2**(i-q),q,i)\n    for i in range(math.floor(n/2)):\n        qc.swap(i,n-(i+1))\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A68F1FABB2431", "submission_order": 1, "result": "WA", "execution_time": "1203 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n\n    n -= 1\n    qc.h(n)\n    for qubit in range(n):\n        qc.cp(math.pi / 2 ** (n - qubit), qubit, n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A68F1FABB2431", "submission_order": 2, "result": "DLE", "execution_time": "1467 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n\n    def qft_rotations(circuit, n):\n        if n == 0:\n            return circuit\n        n -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(math.pi / 2 ** (n - qubit), qubit, n)\n        qft_rotations(circuit, n)\n\n    qft_rotations(qc, n)\n\n    for qubit in range(n // 2):\n        qc.swap(qubit, n - qubit - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A68F1FABB2431", "submission_order": 3, "result": "WA", "execution_time": "1166 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n\n    def qft_rotations(circuit, n):\n        circuit.h(n)\n        for qubit in range(n + 1, circuit.num_qubits):\n            circuit.cp(math.pi / 2 ** (qubit - n), qubit, n)\n\n    for i in range(n):\n        qft_rotations(qc, i)\n\n    for qubit in range(n // 2):\n        qc.swap(qubit, n - qubit - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A68F1FABB2431", "submission_order": 4, "result": "WA", "execution_time": "1414 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n\n    def qft_rotations(circuit, n):\n        circuit.h(n)\n        for qubit in range(n + 1, circuit.num_qubits):\n            circuit.cp(math.pi / 2 ** (n - qubit), qubit, n)\n\n    for i in range(n):\n        qft_rotations(qc, i)\n\n    for qubit in range(n // 2):\n        qc.swap(qubit, n - qubit - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A68F1FABB2431", "submission_order": 5, "result": "WA", "execution_time": "1169 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n\n    for i in range(n):\n        qc.h(i)\n        rotation = math.pi / 2\n        for j in range(i + 1, n):\n            qc.cp(rotation, j, i)\n            rotation /= 2\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A68F1FABB2431", "submission_order": 6, "result": "AC", "execution_time": "2093 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n\n    for i in range(n):\n        qc.h(i)\n        rotation = math.pi / 2\n        for j in range(i + 1, n):\n            qc.cp(rotation, j, i)\n            rotation /= 2\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    qc = qc.reverse_bits()\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6B82BEFFB3F6", "submission_order": 1, "result": "RE", "execution_time": "1117 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n -= 1 # インデックスは0から始める\n    qc.h(n) # Hゲートを最上位量子ビットに適用する\n    for qubit in range(n):\n        # 量子ビットごとに、Indexが小さい方が\n        # 角度の小さい制御回転を実行\n        qc.cp(pi/2**(n-qubit), qubit, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6B82BEFFB3F6", "submission_order": 2, "result": "RE", "execution_time": "1679 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n -= 1 # インデックスは0から始める\n    qc.h(n) # Hゲートを最上位量子ビットに適用する\n    for qubit in range(n):\n        # 量子ビットごとに、Indexが小さい方が\n        # 角度の小さい制御回転を実行\n        qc.cp(np.pi/2**(n-qubit), qubit, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6B82BEFFB3F6", "submission_order": 3, "result": "RE", "execution_time": "1097 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef qft_rotations(qc, n):\n    if n == 0:\n        return qc\n    n -= 1\n    qc.h(n)\n    for qubit in range(n):\n        qc.cp(np.pi/2**(n-qubit), qubit, n)\n    # この関数の最後で、次の量子ビットで同じ関数を再度呼び出します\n    # （関数の前の方ですでにnを1つ減らしています）。\n    qft_rotations(qc, n)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qft_rotations(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6B82BEFFB3F6", "submission_order": 4, "result": "WA", "execution_time": "1601 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef qft_rotations(qc, n):\n    if n == 0:\n        return qc\n    n -= 1\n    qc.h(n)\n    for qubit in range(n):\n        qc.cp(np.pi/2**(n-qubit), qubit, n)\n    # この関数の最後で、次の量子ビットで同じ関数を再度呼び出します\n    # （関数の前の方ですでにnを1つ減らしています）。\n    qft_rotations(qc, n)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qft_rotations(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6B82BEFFB3F6", "submission_order": 5, "result": "RE", "execution_time": "1177 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as n\n\ndef qft_rotations(qc, n):\n    if n == 0:\n        return qc\n    n -= 1\n    qc.h(n)\n    for qubit in range(n):\n        qc.cp(np.pi/2**(n-qubit), qubit, n)\n    # この関数の最後で、次の量子ビットで同じ関数を再度呼び出します\n    # （関数の前の方ですでにnを1つ減らしています）。\n    qft_rotations(qc, n)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qft_rotations(qc, n)\n    swap_registers(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6B82BEFFB3F6", "submission_order": 6, "result": "RE", "execution_time": "1390 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as n\n\ndef qft_rotations(qc, n):\n    if n == 0:\n        return qc\n    n -= 1\n    qc.h(n)\n    for qubit in range(n):\n        qc.cp(np.pi/2**(n-qubit), qubit, n)\n    # この関数の最後で、次の量子ビットで同じ関数を再度呼び出します\n    # （関数の前の方ですでにnを1つ減らしています）。\n    qft_rotations(qc, n)\n\ndef swap_registers(circuit, n):\n    for qubit in range(n//2):\n        circuit.swap(qubit, n-qubit-1)\n    return circuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qft_rotations(qc, n)\n    swap_registers(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6B82BEFFB3F6", "submission_order": 7, "result": "RE", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as n\n\n\ndef qft_rotations(qc, n):\n    if n == 0:\n        return qc\n    n -= 1\n    qc.h(n)\n    for qubit in range(n):\n        qc.cp(np.pi/2**(n-qubit), qubit, n)\n    # この関数の最後で、次の量子ビットで同じ関数を再度呼び出します\n    # （関数の前の方ですでにnを1つ減らしています）。\n    qft_rotations(qc, n)\n\ndef swap_registers(circuit, n):\n    for qubit in range(n//2):\n        circuit.swap(qubit, n-qubit-1)\n    return circuit\n\ndef qft(circuit, n):\n    \"\"\"QFT on the first n qubits in circuit\"\"\"\n    qft_rotations(circuit, n)\n    swap_registers(circuit, n)\n    return circuit\n\ndef inverse_qft(circuit, n):\n    \"\"\"Does the inverse QFT on the first n qubits in circuit\"\"\"\n    # First we create a QFT circuit of the correct size:\n    qft_circ = qft(QuantumCircuit(n), n)\n    # Then we take the inverse of this circuit\n    invqft_circ = qft_circ.inverse()\n    # And add it to the first n qubits in our existing circuit\n    circuit.append(invqft_circ, circuit.qubits[:n])\n    return circuit.decompose() # .decompose() allows us to see the individual gates\n\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc_d = inverse_qft(qc, n)\n    return qc_d\n'''"}
{"problem": "QPC002_B4", "user": "A6B82BEFFB3F6", "submission_order": 8, "result": "WA", "execution_time": "1498 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef qft_rotations(qc, n):\n    if n == 0:\n        return qc\n    n -= 1\n    qc.h(n)\n    for qubit in range(n):\n        qc.cp(np.pi/2**(n-qubit), qubit, n)\n    # この関数の最後で、次の量子ビットで同じ関数を再度呼び出します\n    # （関数の前の方ですでにnを1つ減らしています）。\n    qft_rotations(qc, n)\n\ndef swap_registers(circuit, n):\n    for qubit in range(n//2):\n        circuit.swap(qubit, n-qubit-1)\n    return circuit\n\ndef qft(circuit, n):\n    \"\"\"QFT on the first n qubits in circuit\"\"\"\n    qft_rotations(circuit, n)\n    swap_registers(circuit, n)\n    return circuit\n\ndef inverse_qft(circuit, n):\n    \"\"\"Does the inverse QFT on the first n qubits in circuit\"\"\"\n    # First we create a QFT circuit of the correct size:\n    qft_circ = qft(QuantumCircuit(n), n)\n    # Then we take the inverse of this circuit\n    invqft_circ = qft_circ.inverse()\n    # And add it to the first n qubits in our existing circuit\n    circuit.append(invqft_circ, circuit.qubits[:n])\n    return circuit.decompose() # .decompose() allows us to see the individual gates\n\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc_d = inverse_qft(qc, n)\n    return qc_d\n'''"}
{"problem": "QPC002_B4", "user": "A6EC014FF3B1F", "submission_order": 1, "result": "AC", "execution_time": "1489 ms", "memory": "182 MiB", "code": "'''python\nimport math\n\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for qubit in reversed(range(0, i)):\n            qc.cp(np.pi / 2 **(i - qubit), qubit, i)\n    for i in range(math.floor(n / 2)):\n        qc.swap(i, n - (i + 1))\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 1, "result": "RE", "execution_time": "1067 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 2**(j - i), j, i)\n            \n    for i in range(n//2):\n        qc.swap(i, n - i -1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 2, "result": "RE", "execution_time": "1134 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 2**(j - i), j, i)\n            \n    for i in range(n//2):\n        qc.cx(i, n - i - 1)\n        qc.cx(n - i  - 1, i)\n        qc.cx(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 3, "result": "WA", "execution_time": "1330 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 2**(j - i), j, i)\n            \n    for i in range(n//2):\n        qc.cx(i, n - i - 1)\n        qc.cx(n - i  - 1, i)\n        qc.cx(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 4, "result": "RE", "execution_time": "1273 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 2**(j - i), i, j)\n            \n    for i in range(n//2):\n        qc.cx(i, n - i - 1)\n        qc.cx(n - i  - 1, i)\n        qc.cx(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 5, "result": "WA", "execution_time": "1259 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 2**(j - i), i, j)\n            \n    for i in range(n//2):\n        qc.cx(i, n - i - 1)\n        qc.cx(n - i  - 1, i)\n        qc.cx(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 6, "result": "WA", "execution_time": "1226 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(2 * np.pi / 2**n, i, j)\n            \n    for i in range(n//2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 7, "result": "WA", "execution_time": "1637 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 2**(i - j), j, i)\n            \n    for i in range(n//2):\n        qc.cx(i, n - i - 1)\n        qc.cx(n - i  - 1, i)\n        qc.cx(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 8, "result": "WA", "execution_time": "1084 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi / 2**(i - j), j, i)\n            \n    for i in range(n//2):\n        qc.cx(i, n - i - 1)\n        qc.cx(n - i  - 1, i)\n        qc.cx(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A6EFB5EE5AAF3", "submission_order": 9, "result": "AC", "execution_time": "1705 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi / 2**(i - j), j, i)\n            \n    for i in range(n//2):\n        qc.cx(i, n - i - 1)\n        qc.cx(n - i  - 1, i)\n        qc.cx(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A712415B9295A", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate, QFT\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(QFT(n), range(n))\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2)\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     sv = Statevector.from_label('10')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_B4", "user": "A712415B9295A", "submission_order": 2, "result": "WA", "execution_time": "1763 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate #, QFT\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.append(QFT(n), range(n))\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2)\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     sv = Statevector.from_label('10')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_B4", "user": "A712415B9295A", "submission_order": 3, "result": "WA", "execution_time": "2019 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in range(i):\n            theta = math.pi / 2 ** (i - j)\n            qc.crz(theta, j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A712415B9295A", "submission_order": 4, "result": "DLE", "execution_time": "2090 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in range(i):\n            theta = math.pi / 2 ** (i - j)\n            qc.cp(theta, j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A712415B9295A", "submission_order": 5, "result": "AC", "execution_time": "2343 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            theta = math.pi / 2 ** (i - j)\n            qc.cp(theta, j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7337491DCF55", "submission_order": 1, "result": "RE", "execution_time": "1085 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        # Apply the Hadamard gate to the jth qubit\n        qc.h(j)\n        # Apply the controlled phase rotations\n        for k in range(j+1, n):\n            # Apply the controlled R_k gate\n            qc.cp(np.pi/2**(k-j), j, k)\n\n    # Reverse the order of the qubits\n    for j in range(n//2):\n        qc.swap(j, n-j-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7337491DCF55", "submission_order": 2, "result": "WA", "execution_time": "1165 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        # Apply the Hadamard gate to the jth qubit\n        qc.h(j)\n        # Apply the controlled phase rotations\n        for k in range(j+1, n):\n            # Apply the controlled R_k gate\n            qc.cp(np.pi/2**(k-j), j, k)\n\n    # Reverse the order of the qubits\n    for j in range(n//2):\n        qc.swap(j, n-j-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7337491DCF55", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import QFT\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for j in range(n):\n    #     # Apply the Hadamard gate to the jth qubit\n    #     qc.h(j)\n    #     # Apply the controlled phase rotations\n    #     for k in range(j+1, n):\n    #         # Apply the controlled R_k gate\n    #         qc.cp(np.pi/2**(k-j), j, k)\n\n    # # Reverse the order of the qubits\n    # for j in range(n//2):\n    #     qc.swap(j, n-j-1)\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in range(j):\n            lam = np.pi * (2.0 ** (k - j))\n            qc.cp(lam, k, j)\n    # qc.append(QFT(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7337491DCF55", "submission_order": 4, "result": "WA", "execution_time": "1361 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for j in range(n):\n    #     # Apply the Hadamard gate to the jth qubit\n    #     qc.h(j)\n    #     # Apply the controlled phase rotations\n    #     for k in range(j+1, n):\n    #         # Apply the controlled R_k gate\n    #         qc.cp(np.pi/2**(k-j), j, k)\n\n    # # Reverse the order of the qubits\n    # for j in range(n//2):\n    #     qc.swap(j, n-j-1)\n    for j in reversed(range(n)):\n        qc.h(j)\n        for k in range(j):\n            lam = np.pi * (2.0 ** (k - j))\n            qc.cp(lam, k, j)\n    # qc.append(QFT(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A76D41795AF00", "submission_order": 1, "result": "RE", "execution_time": "1108 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for k in range(n):\n        j = n-k\n        j2 = n-j\n        qc.h(j2-1)\n\n        for i in reversed(range(j-1)):\n            j3 = n - (j-i)\n            i2 = j-1 - i\n            j4 = n-(j-1)\n            qc.cu1(2*np.pi/2**(j3), i2, j4)\n\n        for i in range(n//2):\n            qc.swap(i, n-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A76D41795AF00", "submission_order": 2, "result": "RE", "execution_time": "1455 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for k in range(n):\n        j = n-k\n        # j2 = n-j\n        qc.h(j)\n\n        for i in reversed(range(j-1)):\n            # j3 = n - (j-i)\n            # i2 = j-1 - i\n            # j4 = n-(j-1)\n            qc.cu1(2*np.pi/2**(j-i), i, j-1)\n\n        for i in range(n//2):\n            qc.swap(i, n-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A76D41795AF00", "submission_order": 3, "result": "WA", "execution_time": "1087 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for k in range(n):\n        j = n-1-k\n        # j2 = n-j\n        qc.h(j)\n\n        for i in reversed(range(j-1)):\n            # j3 = n - (j-i)\n            # i2 = j-1 - i\n            # j4 = n-(j-1)\n            qc.cp(2*np.pi/2**(j-i), i, j-1)\n\n        for i in range(n//2):\n            qc.swap(i, n-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A76D41795AF00", "submission_order": 4, "result": "WA", "execution_time": "1091 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for k in range(n):\n        j = n-1-k\n        # qc.h(j)\n        qc.h(k)\n\n        for i in range(j-1):\n        # for i in reversed(range(j-1)):\n            qc.cp(2*np.pi/2**(j-i), i, j-1)\n\n        for i in range(n//2):\n            qc.swap(i, n-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7A7E85D3D133", "submission_order": 1, "result": "WA", "execution_time": "1161 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi/(1<<(j-i)), 0, 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7A7E85D3D133", "submission_order": 2, "result": "WA", "execution_time": "1197 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi/(1<<(j-i)), i, j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7A7E85D3D133", "submission_order": 3, "result": "WA", "execution_time": "1558 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi/(1<<(j-i)), i, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7A7E85D3D133", "submission_order": 4, "result": "AC", "execution_time": "1765 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(i-1, -1, -1):\n            qc.cp(math.pi/(1<<(i-j)), i, j)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 1, "result": "RE", "execution_time": "1107 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        # Apply Hadamard gate to the j-th qubit\n        qc.h(j)\n        \n        # Apply controlled phase gates\n        for k in range(j+1, n):\n            qc.cp(2 * np.pi / (2 ** (k - j + 1)), k, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 2, "result": "RE", "execution_time": "1125 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Implement QFT for little-endian notation\n    for j in range(n):\n        # Apply Hadamard gate to the (n-1-j)-th qubit\n        qc.h(n-1-j)\n        \n        # Apply controlled phase gates\n        for k in range(j+1, n):\n            qc.cp(2 * np.pi / (2 ** (k - j)), n-1-k, n-1-j)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Implement QFT for little-endian notation\n     for j in range(n):\n        # Apply Hadamard gate to the j-th qubit (no reversal needed for little-endian)\n        qc.h(j)\n        \n        # Apply controlled phase gates\n        for k in range(j+1, n):\n            qc.cp(2 * np.pi / (2 ** (k - j + 1)), j, k)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 4, "result": "RE", "execution_time": "1609 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    if not 1 <= n <= 10:\n        raise ValueError(\"n must be between 1 and 10\")\n    \n    qc = QuantumCircuit(n)\n    \n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1, n):\n            qc.cp(2 * pi / (2 ** (k - j + 1)), j, k)\n    \n    \n    \n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 5, "result": "WA", "execution_time": "1166 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1, n):\n            qc.cp(3.14159265358979 / (2 ** (k - j)), j, k)\n\n    \n    \n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 6, "result": "RE", "execution_time": "1293 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    # Apply QFT\n    for qubit in range(n):\n        qc.h(qubit)\n        for other_qubit in range(qubit + 1, n):\n            qc.cp(pi / 2**(other_qubit - qubit), other_qubit, qubit)\n    # Swap qubits to reverse the order\n    for qubit in range(n // 2):\n        qc.swap(qubit, n - qubit - 1)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = qft(n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 7, "result": "WA", "execution_time": "1536 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    for b in reversed(range(5)):\n        i = 0\n        while True:\n            if i + (1<<b) >= n:\n                break\n            qc.cx(i, i + (1<<b))\n            i += (1<<(b+1))\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 8, "result": "RE", "execution_time": "1233 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7E440A66CE26", "submission_order": 9, "result": "AC", "execution_time": "1776 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = qc.compose(qft(n))\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7F49596A25FF", "submission_order": 1, "result": "RE", "execution_time": "1015 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(q[2])\n    qc.cu1(math.pi/2.0, q[1], q[2]) \n    qc.cu1(math.pi/4.0, q[0], q[2]) \n    qc.h(q[1])\n    qc.cu1(math.pi/2.0, q[0], q[1]) \n    qc.h(q[0])\n    qc.swap(q[0],q[2])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7F49596A25FF", "submission_order": 2, "result": "RE", "execution_time": "1036 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(2)\n    qc.cu1(math.pi/2.0, 1, 2) \n    qc.cu1(math.pi/4.0, 0, 2) \n    qc.h(1)\n    qc.cu1(math.pi/2.0, 0, 1) \n    qc.h(0)\n    qc.swap(0,2)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7FA6B3DBDA61", "submission_order": 1, "result": "RE", "execution_time": "1395 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(2**n-1):\n        for i in range(n):\n            if not (l>>i)&1:\n                qc.x(i)\n            theta= math.exp(2*math.pi*l*i*1j/2**n)\n            if n==1:\n                qc.p(theta,n-1)\n            qc.mcp(theta,list(n-1),n-1)\n            if not (l>>i)&1:\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7FA6B3DBDA61", "submission_order": 2, "result": "RE", "execution_time": "1348 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        if not (l>>i)&1:\n            qc.x(i)\n            theta= 2*math.pi*l*i/2**n\n        if n==1:\n            qc.p(theta,0)\n        qc.mcp(theta,list(range(n-1)),n-1)\n        if not (l>>i)&1:\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A7FA6B3DBDA61", "submission_order": 3, "result": "AC", "execution_time": "2367 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A81499C051295", "submission_order": 1, "result": "RE", "execution_time": "1104 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 2**(j - i), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A81499C051295", "submission_order": 2, "result": "RE", "execution_time": "1128 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 2**(j - i), j, i)\n    #for i in range(n // 2):\n    #    qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A81499C051295", "submission_order": 3, "result": "RE", "execution_time": "1141 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i, j)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)    \n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A81499C051295", "submission_order": 4, "result": "RE", "execution_time": "1111 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i, j)\n\n    #for i in range(n // 2):\n    #    qc.swap(i, n - i - 1)    \n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A81499C051295", "submission_order": 5, "result": "RE", "execution_time": "1086 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i, j)\n\n    for i in range(n // 2):\n        qc.cx(i, n - i - 1) \n        qc.cx(n - i - 1, i)\n        qc.cx(i, n - i - 1)   \n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A81499C051295", "submission_order": 6, "result": "AC", "execution_time": "2113 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i, j)\n\n    for i in range(n // 2):\n        qc.cx(i, n - i - 1) \n        qc.cx(n - i - 1, i)\n        qc.cx(i, n - i - 1)   \n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A8216C1037663", "submission_order": 1, "result": "WA", "execution_time": "1231 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], jdx, idx)\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    return qft(n)\n'''"}
{"problem": "QPC002_B4", "user": "A8216C1037663", "submission_order": 2, "result": "WA", "execution_time": "1130 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], jdx, idx)\n\n    qc = qc.reverse_bits()\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    return qft(n)\n'''"}
{"problem": "QPC002_B4", "user": "A8216C1037663", "submission_order": 3, "result": "AC", "execution_time": "1913 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    return qft(n)\n'''"}
{"problem": "QPC002_B4", "user": "A824DF9E957E4", "submission_order": 1, "result": "WA", "execution_time": "2784 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1,n):\n        qc.p(pi*(2**i)/(2**n),i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A824DF9E957E4", "submission_order": 2, "result": "WA", "execution_time": "1909 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,n):\n        qc.h(i)\n    for i in range(0,n):\n        qc.p(pi*(2**i)/(2**(n-1)),i)\n    for i in range(0,n-1):\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A824DF9E957E4", "submission_order": 3, "result": "WA", "execution_time": "1676 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,n):\n        qc.h(i)\n    for i in range(0,n):\n        qc.p(pi*(2**i)/(2**(n-1)),i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A824DF9E957E4", "submission_order": 4, "result": "WA", "execution_time": "1720 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0,n):\n        qc.p(pi*(2**i)/(2**(n-1)),i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A8B0D14DA3F1C", "submission_order": 1, "result": "WA", "execution_time": "1068 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.rz(2*pi/2**(j-i+1), j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A8B0D14DA3F1C", "submission_order": 2, "result": "WA", "execution_time": "1414 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n-1-i)\n        for j in range(i+1, n):\n            qc.rz(2*pi/2**(j-i+1), n-1-j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A8BD8CA411C31", "submission_order": 1, "result": "RE", "execution_time": "1095 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        # Apply the Hadamard gate\n        qc.h(j)\n        \n        # Apply the controlled phase rotation gates\n        for k in range(j + 1, n):\n            qc.cp(np.pi / 2**(k - j), k, j)\n    \n    # Swap qubits to reverse their order\n    for i in range(n // 2):\n        qc.cx(i, n - i - 1)\n        qc.cx(n - i - 1, i)\n        qc.cx(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A8DAF91B4C7FF", "submission_order": 1, "result": "WA", "execution_time": "2046 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i):\n            angle = math.pi / (2**(i - j))\n            qc.cp(angle, j, i)\n    \n    for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A8DAF91B4C7FF", "submission_order": 2, "result": "WA", "execution_time": "1962 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i):\n            angle = math.pi / (2**(i - j))\n            qc.cp(angle, j, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A8DAF91B4C7FF", "submission_order": 3, "result": "AC", "execution_time": "2109 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            angle = math.pi / (2**(i - j))\n            qc.cp(angle, j, i)\n    \n    for i in range(n//2):\n        qc.swap(i, n - 1 - i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9649448D119E", "submission_order": 1, "result": "DLE", "execution_time": "1743 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.initialize([0,1,0,0])\n\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(0, i):\n            qc.cp(2*math.pi/(2**(i-j+1)), j, i)\n    i = 0\n    while i<n-i-1:\n        qc.swap(i, n-i-1)\n        i += 1\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B4", "user": "A9649448D119E", "submission_order": 2, "result": "AC", "execution_time": "1780 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.initialize([0,1,0,0])\n\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(i-1, -1, -1):\n            qc.cp(2*math.pi/(2**(i-j+1)), j, i)\n    \n    # print(qc.depth())\n    i = 0\n    while i<n-i-1:\n        qc.swap(i, n-i-1)\n        i += 1\n    \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 1, "result": "RE", "execution_time": "1006 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        k = 2\n        for j in range(i+1, n):\n            theta = 2 * math.pi / 2 ^ k\n            qc.cp(theta, j, i)\n            k += 1\n    for i in range(n // 2):\n        qc.cx(i, n-i)\n        qc.cx(n-i, i)\n        qc.cx(i, n-i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 2, "result": "RE", "execution_time": "1167 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        # qc.h(i)\n        k = 2\n        for j in range(i+1, n):\n            theta = 2 * math.pi / 2 ^ k\n            qc.cp(theta, j, i)\n            k += 1\n    for i in range(n // 2):\n        qc.cx(i, n-i)\n        qc.cx(n-i, i)\n        qc.cx(i, n-i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 3, "result": "RE", "execution_time": "1151 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        k = 2\n        for j in range(i+1, n):\n            theta = 2 * math.pi / 2 ^ k\n            qc.cp(theta, j, i)\n            k += 1\n    # for i in range(n // 2):\n    #     qc.cx(i, n-i)\n    #     qc.cx(n-i, i)\n    #     qc.cx(i, n-i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 4, "result": "RE", "execution_time": "1184 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.cx(i, n-i)\n            qc.cx(n-i, i)\n            qc.cx(i, n-i)\n    else:\n        qc.h(i)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 5, "result": "RE", "execution_time": "1381 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            # qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.cx(i, n-i)\n            qc.cx(n-i, i)\n            qc.cx(i, n-i)\n    else:\n        # qc.h(i)\n        qc.p(2 * math.pi / 2,)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 6, "result": "RE", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n    else:\n        qc.p(2 * math.pi / 2,)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 7, "result": "RE", "execution_time": "1184 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n--i)\n    else:\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 8, "result": "RE", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n--i)\n    else:\n        qc.h(0)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 9, "result": "RE", "execution_time": "1088 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n    else:\n        qc.h(0)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 10, "result": "RE", "execution_time": "1136 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        # for i in range(n // 2):\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n    else:\n        qc.h(0)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 11, "result": "RE", "execution_time": "1052 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 12, "result": "RE", "execution_time": "1045 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, i, j)\n                k += 1\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 13, "result": "RE", "execution_time": "1154 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(n)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 14, "result": "RE", "execution_time": "1073 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(n-1)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 15, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                # qc.cp(theta, j, i)\n                k += 1\n        qc.h(n-)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n        qc.p(2 * math.pi / 2)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 16, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(n-)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 17, "result": "RE", "execution_time": "1474 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(n-1)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 18, "result": "RE", "execution_time": "1374 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(n-1)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 19, "result": "RE", "execution_time": "1034 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(n-1)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 20, "result": "WA", "execution_time": "1084 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, 1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 21, "result": "WA", "execution_time": "1513 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, 1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 22, "result": "RE", "execution_time": "1111 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,-1,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, 1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 23, "result": "RE", "execution_time": "1195 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,-1,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, 0, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 24, "result": "RE", "execution_time": "1276 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 25, "result": "RE", "execution_time": "1141 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 26, "result": "WA", "execution_time": "1057 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 27, "result": "WA", "execution_time": "1168 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 28, "result": "WA", "execution_time": "1155 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 29, "result": "RE", "execution_time": "1172 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(0, n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 30, "result": "RE", "execution_time": "1090 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(0, n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(n-1)\n        # for i in range(n // 2):\n        #     qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 31, "result": "RE", "execution_time": "1073 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(0, n-1):\n            qc.h(i)\n            k = 2\n            for j in range(i+1, n):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(n-1)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 32, "result": "WA", "execution_time": "1144 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 33, "result": "WA", "execution_time": "1459 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 34, "result": "RE", "execution_time": "1038 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 35, "result": "WA", "execution_time": "1506 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 36, "result": "RE", "execution_time": "1053 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1,-1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 37, "result": "RE", "execution_time": "1138 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1,-1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 38, "result": "RE", "execution_time": "1382 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        for i in range(n-1):\n            ii = n-1-i\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            for j in range(ii):\n                jj = n-2-j\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, jj, ii)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 39, "result": "RE", "execution_time": "1188 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        for i in range(n-1):\n            ii = n-1-i\n            qc.h(ii)\n            k = 2\n            # for j in range(i-1, -1):\n            for j in range(ii):\n                jj = n-2-j\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, jj, ii)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 40, "result": "RE", "execution_time": "1286 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        for i in range(n-1):\n            ii = n-1-i\n            qc.h(ii)\n            k = 2\n            # for j in range(i-1, -1):\n            for j in range(ii):\n                jj = ii-1-j\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, jj, ii)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 41, "result": "RE", "execution_time": "1240 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        for i in range(n-1):\n            ii = n-1-i\n            qc.h(ii)\n            k = 2\n            # for j in range(i-1, -1):\n            for j in range(ii):\n                jj = ii-1-j\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, jj, ii)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 42, "result": "WA", "execution_time": "1162 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        for i in range(n // 2):\n            # qc.swap(i, n-1-i)\n            qc.cx(i, n-1-i)\n            qc.cx(n-1-i, i)\n            qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 43, "result": "WA", "execution_time": "1084 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 44, "result": "RE", "execution_time": "1115 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1,-1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 45, "result": "WA", "execution_time": "1087 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            j = i -1\n            while j >= 0:\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 46, "result": "RE", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        i = n - 1 \n        while i >= 1:\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            j = i - 1\n            while j >= 0:\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 47, "result": "RE", "execution_time": "1269 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        i = n - 1 \n        while i >= 1:\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            j = i - 1\n            while j >= 0:\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n            i -= 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 48, "result": "RE", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        i = n - 1 \n        while i >= 1:\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            j = i - 1\n            while j >= 0:\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n            i -= 1\n        qc.h(0)\n        # for i in range(n // 2):\n        #     # qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 49, "result": "RE", "execution_time": "1054 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        i = n - 1 \n        while i >= 1:\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            j = i - 1\n            while j >= 0:\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n            i -= 1\n        qc.h(0)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 50, "result": "RE", "execution_time": "1195 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        i = n - 1 \n        while i > 0:\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            j = i - 1\n            while j >= 0:\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n            i -= 1\n        qc.h(0)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 51, "result": "RE", "execution_time": "1320 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        # for i in range(n-1,0):\n        i = n - 1 \n        while i > 0:\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            j = i - 1\n            while j >= 0:\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n            i = i - 1\n        qc.h(0)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 52, "result": "WA", "execution_time": "1126 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            # for j in range(i-1, -1):\n            j = i - 1\n            while j >= 0:\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n        qc.h(0)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 53, "result": "WA", "execution_time": "1235 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,0):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n        qc.h(0)\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n        #     qc.cx(i, n-1-i)\n        #     qc.cx(n-1-i, i)\n        #     qc.cx(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 54, "result": "WA", "execution_time": "1039 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n                j -= 1\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 55, "result": "WA", "execution_time": "1481 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n > 1:\n        for i in range(n-1,-1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n\n    else:\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 56, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n        for i in range(n-1, -1, -1):\n            qc.h(i)\n            k = 2\n            for j in range(i-1, -1, -):\n                theta = 2 * math.pi / 2 ^ k\n                qc.cp(theta, j, i)\n                k += 1\n        for i in range(n // 2):\n            qc.swap(i, n-1-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A97CA62BC09EE", "submission_order": 57, "result": "AC", "execution_time": "1696 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        k = 2\n        for j in range(i-1, -1, -1):\n            theta = 2 * math.pi / 2 ** k\n            qc.cp(theta, j, i)\n            k += 1\n    for i in range(n // 2):\n        qc.swap(i, n-1-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9BB84B4F7896", "submission_order": 1, "result": "RE", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for qubit in range(n):\n        qc.h(qubit)\n        for k in range(qubit + 1, n):\n            qc.cp(2 * np.pi / (2 ** (k - qubit + 1)), k, qubit)\n    for qubit in range(n // 2):\n        qc.swap(qubit, n - qubit - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9BB84B4F7896", "submission_order": 2, "result": "RE", "execution_time": "1164 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for qubit in range(n):\n        qc.h(qubit)\n        for k in range(qubit + 1, n):\n            qc.cp(2 * np.pi / (2 ** (k - qubit + 1)), k, qubit)\n    for qubit in range(n // 2):\n        q.swap(qubit, n - qubit - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9BB84B4F7896", "submission_order": 3, "result": "RE", "execution_time": "1064 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for qubit in range(0,n):\n        qc.h(qubit)\n        for k in range(qubit + 1, n):\n            qc.cp(2 * np.pi / (2 ** (k - qubit + 1)), k, qubit)\n    for qubit in range(0, n // 2):\n        q.swap(qubit, n - qubit - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9BB84B4F7896", "submission_order": 4, "result": "RE", "execution_time": "1077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for qubit in range(n):\n        qc.h(qubit)\n        for k in range(qubit + 1, n):\n            qc.cp(2 * np.pi / (2 ** (k - qubit + 1)), k, qubit)\n    for qubit in range(n // 2):\n        q.swap(qubit, n - qubit - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9BB84B4F7896", "submission_order": 5, "result": "WA", "execution_time": "1450 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef qft(circuit, n):\n    for qubit in range(n):\n        circuit.h(qubit)\n        for k in range(qubit + 1, n):\n            circuit.cp(2 * np.pi / (2 ** (k - qubit + 1)), k, qubit)\n    for qubit in range(n // 2):\n        circuit.swap(qubit, n - qubit - 1)\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qft(qc, n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9C3D3980B8D3", "submission_order": 1, "result": "RE", "execution_time": "1079 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc += QFT(num_qubits=n, approximation_degree=0, do_swaps=True, inverse=False, insert_barriers=False, name='qft')\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9C3D3980B8D3", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc += QFT(num_qubits=n, approximation_degree=0, do_swaps=True, inverse=False, insert_barriers=False, name='qft')\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9C3D3980B8D3", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap_registers(circuit, n):\n        for qubit in range(n//2):\n            circuit.swap(qubit, n-qubit-1)\n        return circuit\n\n    def qft(circuit, n):\n        \"\"\"QFT on the first n qubits in circuit\"\"\"\n        qft_rotations(circuit, n)\n        swap_registers(circuit, n)\n        return circuit\n\n    def qft_rotations(circuit, n):\n        \"\"\"Performs qft on the first n qubits in circuit (without swaps)\"\"\"\n        if n == 0:\n            return circuit\n        n -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(pi/2**(n-qubit), qubit, n)\n        # At the end of our function, we call the same function again on\n        # the next qubits (we reduced n by one earlier in the function)\n        qft_rotations(circuit, n)\n    # Let's see how it looks:\n    qft(qc,n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9C3D3980B8D3", "submission_order": 4, "result": "RE", "execution_time": "1145 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap_registers(circuit, n):\n        for qubit in range(n//2):\n            circuit.swap(qubit, n-qubit-1)\n        return circuit\n\n    def qft(circuit, n):\n        \"\"\"QFT on the first n qubits in circuit\"\"\"\n        qft_rotations(circuit, n)\n        swap_registers(circuit, n)\n        return circuit\n\n    def qft_rotations(circuit, n):\n        \"\"\"Performs qft on the first n qubits in circuit (without swaps)\"\"\"\n        if n == 0:\n            return circuit\n        n -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(pi/2**(n-qubit), qubit, n)\n        # At the end of our function, we call the same function again on\n        # the next qubits (we reduced n by one earlier in the function)\n        qft_rotations(circuit, n)\n    # Let's see how it looks:\n    qft(qc,n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9C3D3980B8D3", "submission_order": 5, "result": "DLE", "execution_time": "1139 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap_registers(circuit, n):\n        for qubit in range(n//2):\n            circuit.swap(qubit, n-qubit-1)\n        return circuit\n\n    def qft(circuit, n):\n        \"\"\"QFT on the first n qubits in circuit\"\"\"\n        qft_rotations(circuit, n)\n        swap_registers(circuit, n)\n        return circuit\n\n    def qft_rotations(circuit, n):\n        \"\"\"Performs qft on the first n qubits in circuit (without swaps)\"\"\"\n        if n == 0:\n            return circuit\n        n -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(pi/2**(n-qubit), qubit, n)\n        # At the end of our function, we call the same function again on\n        # the next qubits (we reduced n by one earlier in the function)\n        qft_rotations(circuit, n)\n    # Let's see how it looks:\n    qft(qc,n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "A9E441280E0C2", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFTGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QFTGate(n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA0897279810A", "submission_order": 1, "result": "RE", "execution_time": "1080 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(2 * np.pi / 2**(j-i+1), j, i)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA0897279810A", "submission_order": 2, "result": "WA", "execution_time": "1161 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(2 * np.pi / 2**(j-i+1), j, i)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA107A4614541", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        for j in reversed(range(i))\n            qc.cp(math.pi / (2 ** (i - j)), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA107A4614541", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i))\n            qc.cp(math.pi / (2 ** (i - j)), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA107A4614541", "submission_order": 3, "result": "AC", "execution_time": "2069 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / (2 ** (i - j)), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA1808EA723C6", "submission_order": 1, "result": "WA", "execution_time": "1462 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(np.pi/(2.0 ** (j-(i+1)+1)), j, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA1808EA723C6", "submission_order": 2, "result": "WA", "execution_time": "1103 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n    #     for j in range(i+1,n):\n    #         qc.cp(np.pi/(2.0 ** (j-(i+1)+1)), j, i)\n\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in range(i):\n            qc.cp(np.pi/(2.0 ** (i-j)), j, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA1808EA723C6", "submission_order": 3, "result": "WA", "execution_time": "1511 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n    #     for j in range(i+1,n):\n    #         qc.cp(np.pi/(2.0 ** (j-(i+1)+1)), j, i)\n\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi/(2.0 ** (i-j)), j, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA1808EA723C6", "submission_order": 4, "result": "AC", "execution_time": "2299 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #     qc.h(i)\n    #     for j in range(i+1,n):\n    #         qc.cp(np.pi/(2.0 ** (j-(i+1)+1)), j, i)\n\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi/(2.0 ** (i-j)), j, i)\n\n    for i in range(n):\n        if i < n-1-i:\n            qc.swap(i,n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 1, "result": "WA", "execution_time": "1049 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for qubit in range(n):\n        qc.h(qubit)\n        for j in range(qubit):\n            qc.cp(pi / 2**(qubit - j), j, qubit)\n\n    for qubit in range(n // 2):\n        qc.swap(qubit, n - qubit - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 2, "result": "WA", "execution_time": "1166 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for qubit in range(n):\n        qc.h(qubit)\n        for j in range(qubit):\n            qc.cp(pi / 2**(qubit - j), j, qubit)    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 3, "result": "DLE", "execution_time": "1444 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef qft_rotations(circuit, n):\n    \"\"\"Performs the QFT on the first n qubits in the circuit.\"\"\"\n    if n == 0:\n        return circuit\n    n -= 1\n    circuit.h(n)\n    for qubit in range(n):\n        circuit.cp(np.pi / 2**(n - qubit), qubit, n)\n    qft_rotations(circuit, n)\n\ndef swap_registers(circuit, n):\n    \"\"\"Swaps the qubits to correct the ordering after QFT.\"\"\"\n    for qubit in range(n // 2):\n        circuit.swap(qubit, n - qubit - 1)\n    return circuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply the QFT\n    qft_rotations(qc, n)\n    # Swap the qubits to correct the ordering\n    swap_registers(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 4, "result": "WA", "execution_time": "1075 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef qft_rotations_optimized(circuit, n):\n    \"\"\"Performs the QFT on the first n qubits in the circuit.\"\"\"\n    for i in range(n):\n        circuit.h(i)\n        for j in range(i + 1, n):\n            circuit.cp(np.pi / 2**(j - i), j, i)\n    \ndef swap_registers(circuit, n):\n    \"\"\"Swaps the qubits to correct the ordering after QFT.\"\"\"\n    for qubit in range(n // 2):\n        circuit.swap(qubit, n - qubit - 1)\n    return circuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply the optimized QFT\n    qft_rotations_optimized(qc, n)\n    # Swap the qubits to correct the ordering\n    swap_registers(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 5, "result": "WA", "execution_time": "1585 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef qft_rotations(circuit, n):\n    \"\"\"Performs the QFT on the first n qubits in the circuit.\"\"\"\n    for j in range(n):\n        circuit.h(j)\n        for k in range(j + 1, n):\n            circuit.cp(np.pi / 2**(k - j), k, j)\n\ndef swap_registers(circuit, n):\n    \"\"\"Swaps the qubits to correct the ordering after QFT.\"\"\"\n    for qubit in range(n // 2):\n        circuit.swap(qubit, n - qubit - 1)\n    return circuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply the QFT\n    qft_rotations(qc, n)\n    # Swap the qubits to correct the ordering\n    swap_registers(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 6, "result": "WA", "execution_time": "1065 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef optimized_qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for j in range(n):\n        for k in range(j):\n            qc.cp(np.pi / 2**(j - k), n - 1 - j, n - 1 - k)\n        qc.h(n - 1 - j)\n    \n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    return optimized_qft(n)\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 7, "result": "WA", "execution_time": "1568 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef qft_rotations(circuit, n):\n    \"\"\"Performs the QFT on the first n qubits in the circuit.\"\"\"\n    if n == 0:\n        return circuit\n    n -= 1\n    circuit.h(n)\n    for qubit in range(n):\n        circuit.cp(np.pi / 2**(n - qubit), qubit, n)\n    qft_rotations(circuit, n)\n\ndef swap_registers(circuit, n):\n    \"\"\"Swaps the qubits to correct the ordering after QFT.\"\"\"\n    for qubit in range(n // 2):\n        circuit.swap(qubit, n - qubit - 1)\n    return circuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply the QFT\n    qft_rotations(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 8, "result": "WA", "execution_time": "1108 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        # Apply Hadamard gate\n        qc.h(i)\n        # Apply controlled phase rotation gates\n        for j in range(i + 1, n):\n            qc.cp(pi / 2**(j - i), j, i)\n    # Reverse the order of qubits\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    return qft(n)\n\n# Example usage:\nqc = solve(2)\nprint(qc)\n'''"}
{"problem": "QPC002_B4", "user": "AA19E81C076C6", "submission_order": 9, "result": "WA", "execution_time": "1229 ms", "memory": "151 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(pi / 2**(j - i), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    return qft(n)\n'''"}
{"problem": "QPC002_B4", "user": "AA4D538AC9A48", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n \n \ndef solve(n: int) -> QuantumCircuit:\n    #qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QFT(n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA5C4EF604A56", "submission_order": 1, "result": "RE", "execution_time": "1203 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(U1Gate(pi/2**(j-i)).control(j), [j, i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA5C4EF604A56", "submission_order": 2, "result": "AC", "execution_time": "1651 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [j, i])\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA6F97A66AE8B", "submission_order": 1, "result": "WA", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n      for j in range(1, n-i):\n        qc.cu(0, 2*pi/(2**(j+1)),0,0,i+j,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA6F97A66AE8B", "submission_order": 2, "result": "WA", "execution_time": "1294 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n      for j in range(1, n-i):\n        qc.cu(0,0,0, 2*pi/(2**(j+1)),i+j,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA6F97A66AE8B", "submission_order": 3, "result": "WA", "execution_time": "1114 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n      for j in range(1, n-i):\n        qc.cu(0,0,0, 2*pi/(2**(j+2)),i+j,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA6F97A66AE8B", "submission_order": 4, "result": "WA", "execution_time": "1467 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n      for j in range(1, n-i):\n        qc.cu(0,0,0, 2*pi/(2**j),i+j,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA9E23543A0BA", "submission_order": 1, "result": "WA", "execution_time": "1219 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            theta = 2 * pi / (2 ** j)\n            qc.cp(theta, j, i)\n\n    for i in range(n):\n        j = n - 1 - i\n        if i >= j:\n            break\n        qc.swap(i, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA9E23543A0BA", "submission_order": 2, "result": "WA", "execution_time": "1097 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            theta = 2 * pi / (2 ** (j + 1))\n            qc.cp(theta, j, i)\n\n    for i in range(n):\n        j = n - 1 - i\n        if i >= j:\n            break\n        qc.swap(i, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA9E23543A0BA", "submission_order": 3, "result": "WA", "execution_time": "1157 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            theta = 2 * pi / (2 ** (j + 1 - i))\n            qc.cp(theta, j, i)\n\n    for i in range(n):\n        j = n - 1 - i\n        if i >= j:\n            break\n        qc.swap(i, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AA9E23543A0BA", "submission_order": 4, "result": "AC", "execution_time": "1772 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.x(0)\n    # Write your code here:\n    for i in range(n):\n        j = n - 1 - i\n        if i >= j:\n            break\n        qc.swap(i, j)\n\n    for i in range(n):\n        qc.h(i)\n        print(\"start\", i + 1)\n        for j in range(i + 1, n):\n            theta = 2 * pi / (2 ** (j + 1 - i))\n            print(j + 1 - i)\n            qc.cp(theta, j, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AAE2C69A99578", "submission_order": 1, "result": "WA", "execution_time": "1036 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(2 * math.pi / pow(2, j + 1) , j, i)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AAE2C69A99578", "submission_order": 2, "result": "WA", "execution_time": "1114 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(2 * math.pi / pow(2, j + 1) , j, i)\n            \n    for i in range(n):\n        j = (n - 1 - i)\n        if i < j:\n            qc.swap(i, j)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AAE2C69A99578", "submission_order": 3, "result": "WA", "execution_time": "1062 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(2 * math.pi / pow(2, j - i + 1) , j, i)\n            \n    for i in range(n):\n        j = (n - 1 - i)\n        if i < j:\n            qc.swap(i, j)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AAE2C69A99578", "submission_order": 4, "result": "WA", "execution_time": "1604 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(2 * math.pi / pow(2, j - i + 1) , j, i)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AAE2C69A99578", "submission_order": 5, "result": "WA", "execution_time": "1163 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(2 * math.pi / pow(2, j - i + 1) , j, i)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AAE2C69A99578", "submission_order": 6, "result": "WA", "execution_time": "1659 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(0, i):\n            qc.cp(2 * math.pi / pow(2, i - j + 1) , j, i)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AAE2C69A99578", "submission_order": 7, "result": "WA", "execution_time": "1025 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(2 * math.pi / pow(2, i - j + 1) , j, i)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AAE2C69A99578", "submission_order": 8, "result": "AC", "execution_time": "1885 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(2 * math.pi / pow(2, i - j + 1) , j, i)\n            \n    for i in range(n):\n        j = (n - 1 - i)\n        if i < j:\n            qc.swap(i, j)\n            \n        \n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB1333B95C515", "submission_order": 1, "result": "DLE", "execution_time": "1611 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\nimport math\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n - 1, -1, -1):\n    qc.h(i)\n    for j in range(i):\n      qc.append(PhaseGate(math.pi * 2 * math.pow(2, j - 1 - i)).control(1), [i, j])\n  for i in range(n // 2):\n    qc.cx(i, n - 1 - i)\n    qc.cx(n - 1 - i, i)\n    qc.cx(i, n - 1 - i)\n  return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB1333B95C515", "submission_order": 2, "result": "WA", "execution_time": "1324 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\nimport math\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n - 1, -1, -1):\n    for j in range(n - 1, i + 1, -1):\n      qc.append(PhaseGate(math.pi * 2 * math.pow(2, i - 1 - j)).control(1), [i, j])\n    qc.h(i)\n  for i in range(n // 2):\n    qc.cx(i, n - 1 - i)\n    qc.cx(n - 1 - i, i)\n    qc.cx(i, n - 1 - i)\n  return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB1333B95C515", "submission_order": 3, "result": "AC", "execution_time": "1731 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\nimport math\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n - 1, -1, -1):\n    for j in range(n - 1, i, -1):\n      qc.append(PhaseGate(math.pi * 2 * math.pow(2, i - 1 - j)).control(1), [i, j])\n    qc.h(i)\n  for i in range(n // 2):\n    qc.cx(i, n - 1 - i)\n    qc.cx(n - 1 - i, i)\n    qc.cx(i, n - 1 - i)\n  return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 1, "result": "RE", "execution_time": "1207 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        # Apply Hadamard gate to the i-th qubit\n        qc.h(i)\n        \n        # Apply controlled phase gates\n        for j in range(i + 1, n):\n            angle = np.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)  \n    \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 2, "result": "RE", "execution_time": "1191 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        # Apply Hadamard gate to the i-th qubit\n        qc.h(i)\n        \n        # Apply controlled phase gates\n        for j in range(i + 1, n):\n            angle = np.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)  # Controlled Phase gate (CPhase)\n    \n    # Reverse the qubits order to match little-endian format\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 3, "result": "WA", "execution_time": "1055 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply QFT\n    for i in range(n):\n        # Apply Hadamard gate to the i-th qubit\n        qc.h(i)\n        \n        # Apply controlled phase gates\n        for j in range(i + 1, n):\n            angle = np.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)  # Controlled Phase gate (CPhase)\n    \n    # Reverse the qubits order to match little-endian format\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 4, "result": "WA", "execution_time": "1535 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n\n    for i in range(n):\n        # Apply Hadamard gate to the i-th qubit\n        qc.h(i)\n        \n        # Apply controlled phase gates\n        for j in range(i + 1, n):\n            angle = np.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)  # Controlled Phase gate (CPhase)\n    \n    # Reverse the qubits order to match little-endian format\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 5, "result": "RE", "execution_time": "1059 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply controlled phase shifts\n    for i in range(n):\n        for j in range(i+1, n):\n            qc.cp(2 * math.pi / (2 ** (j - i)), i, j)\n    \n    # Apply Hadamard gates to all qubits again\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 6, "result": "WA", "execution_time": "1267 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply controlled phase shifts\n    for i in range(n):\n        for j in range(i+1, n):\n            qc.cp(2 * math.pi / (2 ** (j - i)), i, j)\n    \n    # Apply Hadamard gates to all qubits again\n    for i in range(n):\n        qc.h(i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 7, "result": "WA", "execution_time": "1123 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply controlled phase shifts\n    for i in range(n):\n        for j in range(i+1, n):\n            qc.cp(2 * math.pi / (2 ** (j - i + 1)), j, i)\n    \n    # Swap qubits to get the correct order\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 8, "result": "WA", "execution_time": "1269 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Apply QFT\n    for i in range(n):\n        # Apply Hadamard gate to the i-th qubit\n        qc.h(i)\n        \n        # Apply controlled phase gates\n        for j in range(i + 1, n):\n            angle = np.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)  # Controlled Phase gate (CPhase)\n    \n    # Reverse the qubit order to match little-endian format\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB3DB8CEDD89C", "submission_order": 9, "result": "WA", "execution_time": "1161 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Apply QFT\n    for i in range(n):\n        # Apply Hadamard gate to the i-th qubit\n        qc.h(i)\n        \n        # Apply controlled phase gates\n        for j in range(i + 1, n):\n            angle = np.pi / (2 ** (j - i))\n            qc.cp(angle, j, i)  # Controlled Phase gate (CPhase)\n    \n    # Reverse the qubit order to match little-endian format\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB7DB46EEAB99", "submission_order": 1, "result": "WA", "execution_time": "1668 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Quantum Fourier Transform\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi / (2**(j-i)), j, i)\n    \n    # Swapping qubits\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB7DB46EEAB99", "submission_order": 2, "result": "RE", "execution_time": "1160 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    \"\"\"\n    量子フーリエ変換の量子回路を生成する関数\n\n    Args:\n        n: 量子ビット数\n\n    Returns:\n        QuantumCircuit: 量子フーリエ変換の量子回路\n    \"\"\"\n\n    qc = QuantumCircuit(n)\n\n    # 量子フーリエ変換の回路を構築\n    for i in range(n):\n        # Hadamardゲートを適用\n        qc.h(i)\n        # Controlled-phaseゲートを適用\n        for j in range(i):\n            qc.cp(np.pi / 2**(i-j), j, i)\n\n    # 量子ビットの順番を逆転\n    for qubit in range(n//2):\n        qc.swap(qubit, n-qubit-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AB95713CDED22", "submission_order": 1, "result": "WA", "execution_time": "1256 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import MCPhaseGate\n##from qiskit.quantum_info import Statevector\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #state_vector = [0, 0, 1, 0] #2量子系において初期状態を与える\n    #qc.initialize(state_vector, [0, 1]) #量子系の初期状態を変更\n\n    # QFTの実装（リトルエンディアン）\n    cnt = list(range(0,n,1))\n    prev = list(range(0,n,1))\n    for i in range(n):\n        cnt[i]=0\n    \n\n    for i in range(25):\n        for j in range(n-1,-1,-1):\n            if prev[j]!=0:\n                continue\n            if cnt[j]==0:\n                qc.h(j)\n                cnt[j]+=1\n            elif cnt[j]+j>=n:\n                continue\n            else:\n                k = cnt[j]+1\n                qc.cp(2*np.pi/(2**k),j+k-1,j)\n                cnt[j]+=1\n                prev[j+k-1]-=1\n\n    return qc\n\n\n\nqc = solve(2)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_B4", "user": "AB95713CDED22", "submission_order": 2, "result": "AC", "execution_time": "1549 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import MCPhaseGate\n#from qiskit.quantum_info import Statevector\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # state_vector = [0, 1, 0, 0] #2量子系において初期状態を与える\n    # qc.initialize(state_vector, [0, 1]) #量子系の初期状態を変更\n\n    # QFTの実装（リトルエンディアン）\n    cnt = list(range(0,n,1))\n    prev = list(range(0,n,1))\n    for i in range(n):\n        cnt[i]=0\n    \n    for i in range(n):\n        x = i\n        y = n-1-i\n        if x>=y :\n            break\n        qc.swap(x,y)\n    \n\n    for i in range(25):\n        for j in range(n-1,-1,-1):\n            if prev[j]!=0:\n                continue\n            if cnt[j]==0:\n                qc.h(j)\n                cnt[j]+=1\n            elif cnt[j]+j>=n:\n                continue\n            else:\n                k = cnt[j]+1\n                qc.cp(2*np.pi/(2**k),j+k-1,j)\n                cnt[j]+=1\n                prev[j+k-1]-=1\n\n    return qc\n\n\n\nqc = solve(2)\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_B4", "user": "ABD337C3779D5", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    # qc = QuantumCircuit(n)\n    qc = QFT(n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABD337C3779D5", "submission_order": 2, "result": "WA", "execution_time": "1529 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for j in range(0, n):\n        qc.h(0)\n        for i in range(j+1, n):\n            qc.cu(1/2**(i-j)*math.pi, 0, 0, 0, i, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABD337C3779D5", "submission_order": 3, "result": "WA", "execution_time": "1161 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for j in range(0, n):\n        qc.h(0)\n        for i in range(j+1, n):\n            qc.cp(1/2**(i-j)*math.pi, i, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABD337C3779D5", "submission_order": 4, "result": "WA", "execution_time": "1274 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for j in range(0, n):\n        qc.h(j)\n        for i in range(j+1, n):\n            qc.cp(1/2**(i-j)*math.pi, i, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABD337C3779D5", "submission_order": 5, "result": "WA", "execution_time": "1465 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for j in reversed(range(0, n)):\n        qc.h(j)\n        num_entanglements = max(\n            0, j - max(0, 0 - (n - j - 1)))\n        for k in reversed(range(j-num_entanglements, j)):\n            lam = math.pi * (2.0 ** (k - j))\n            qc.cp(lam, j, k)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABD337C3779D5", "submission_order": 6, "result": "WA", "execution_time": "1234 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for j in reversed(range(0, n)):\n        qc.h(j)\n        for k in reversed(range(0, j)):\n            lam = math.pi * (2.0 ** (k - j))\n            qc.cp(lam, j, k)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABD337C3779D5", "submission_order": 7, "result": "AC", "execution_time": "1742 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for j in reversed(range(0, n)):\n        qc.h(j)\n        for k in reversed(range(0, j)):\n            lam = math.pi * (2.0 ** (k - j))\n            qc.cp(lam, j, k)\n\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom np import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    angles = [np.pi / 2**(i) for i in range(1, n)]\n    for j in range(n):\n        qc.h(j)\n        for i, angle in enumerate(angles):\n            qc.cp(angle, j + i + 1, j)\n            if j + i + 1 >= n - 1:\n                break\n\n    # ビットの順序を逆にする\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 2, "result": "RE", "execution_time": "1106 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    angles = [np.pi / 2**(i) for i in range(1, n)]\n    for j in range(n):\n        qc.h(j)\n        for i, angle in enumerate(angles):\n            qc.cp(angle, j + i + 1, j)\n            if j + i + 1 >= n - 1:\n                break\n\n    # ビットの順序を逆にする\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 3, "result": "WA", "execution_time": "1201 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            qc.cp(pi/2**(j-i),j,i)\n\n    # ビットの順序を逆にする\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 4, "result": "RE", "execution_time": "1186 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        qc.h(q[j])\n        for k in range(j+1,n):\n            qc.cu1(math.pi/float(2**(k-j)), q[k], q[j])\n        qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 5, "result": "RE", "execution_time": "1082 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        qc.h(q[j])\n        for k in range(j+1,n):\n            qc.cu1(pi/float(2**(k-j)), q[k], q[j])\n        qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 6, "result": "RE", "execution_time": "1183 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1,n):\n            qc.cu1(pi/float(2**(k-j)), k, j)\n        qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 7, "result": "RE", "execution_time": "1077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(np.pi/float(2**(j-i)), j, i)\n            \n    # ビットリバース\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n        \n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 8, "result": "RE", "execution_time": "1204 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cu1(np.pi/float(2**(j-i)), j, i)          \n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 9, "result": "WA", "execution_time": "1121 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.h(i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 10, "result": "RE", "execution_time": "1136 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(np.pi / float(2**(j-i)), i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 11, "result": "RE", "execution_time": "1179 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(np.pi/float(2**(j-i)),i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 12, "result": "RE", "execution_time": "1066 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cu1(np.pi/float(2**(j-i)),i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABDBE260A0201", "submission_order": 13, "result": "RE", "execution_time": "1013 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cu1(np.pi/float(2**(j-i)),i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 1, "result": "RE", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range (n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2^(b)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 2, "result": "WA", "execution_time": "1140 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n=1\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2^(b)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 3, "result": "RE", "execution_time": "1085 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n=5\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2^(b)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 4, "result": "RE", "execution_time": "1408 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n=3\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2^(b)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 5, "result": "RE", "execution_time": "1743 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n=2\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2^(b)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 6, "result": "RE", "execution_time": "1592 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n=2\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(b)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 7, "result": "WA", "execution_time": "1201 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(b)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        k=2\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(k)), b, a)\n            k++\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 9, "result": "WA", "execution_time": "1555 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        k=2\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(k)), b, a)\n            k = k+1\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 10, "result": "WA", "execution_time": "1150 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(b-a+1)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(b-a+)), b, a)\n    swaps=int(n/2)\n    for a in range(swaps):\n        qc.swap(a,n-1-a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 12, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(b-a+)), b, a)\n    swaps=int(n/2)\n    for a in range(swaps):\n        qc.swap(a, n-a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 13, "result": "WA", "execution_time": "1287 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(b-a+1)), b, a)\n    swaps=int(n/2)\n    for a in range(swaps):\n        qc.swap(a, n-a-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 14, "result": "WA", "execution_time": "1504 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(b-a+1)), b, a)\n    swaps=int(n//2)\n    for a in range(swaps):\n        qc.swap(a, n-a-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 15, "result": "WA", "execution_time": "1126 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(2*math.pi/(2**(b-a)), b, a)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 16, "result": "WA", "execution_time": "1436 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.h(a)\n        for b in range(a+1, n):\n            qc.cp(math.pi/(2**(b-a)), b, a)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ABE931F9676B0", "submission_order": 17, "result": "AC", "execution_time": "1794 ms", "memory": "183 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7C21331EE7B", "submission_order": 1, "result": "RE", "execution_time": "1085 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n -= 1\n    qc.h(n) \n    for qubit in range(n):\n        qc.cp(math.pi/2**(n-qubit), qubit, n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 1, "result": "RE", "execution_time": "1089 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1)[::-1]:\n            print(n-j-1, i)\n            qc.cp(2*pi/(2**(n-j-i)), n-j-1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 2, "result": "RE", "execution_time": "1801 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)[::-1]:\n        qc.h(i)\n        for j in range(n-i-1):\n            print(n-j-1, i)\n            qc.cp(2*pi/(2**(n-j-i)), n-j-1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 3, "result": "RE", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1)[::-1]:\n            qc.cp(2*pi/(2**(n-j-i)), n-j-1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 4, "result": "RE", "execution_time": "1078 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)[::-1]:\n        qc.h(i)\n        for j in range(i):\n            qc.cp(2*pi/(2**(i)), i, i-j-1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 5, "result": "WA", "execution_time": "1290 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)[::-1]:\n        qc.h(i)\n        for j in range(i):\n            qc.cp(2*pi/(2**(i)), i, i-j-1)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 6, "result": "WA", "execution_time": "1376 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1)[::-1]:\n            qc.cp(2*pi/(2**(n-j-i)), n-j-1, i)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 7, "result": "WA", "execution_time": "1247 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)[::-1]:\n        qc.h(i)\n        for j in range(i):\n            qc.cp(2*pi/(2**(j+2)), i, i - j - 1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 8, "result": "WA", "execution_time": "1425 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1)[::-1]:\n            qc.cp(2*pi/(2**(n-j-i)), i, n-j-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 9, "result": "WA", "execution_time": "1593 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1):\n            qc.cp(2*pi/(2**(j+2)), i, n-j-1)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 10, "result": "WA", "execution_time": "1476 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1):\n            qc.cp(2*pi/(2**(j+2)), n-j-1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 11, "result": "WA", "execution_time": "1150 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1)[::-1]:\n            qc.cp(2*pi/(2**(n-j-i)), n-j-1, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 12, "result": "RE", "execution_time": "1374 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1)[::-1]:\n            qc.cp(2*pi/(2**(n-j-i)), n-j-1, i)\n    qc.swap(0,4)\n    qc.swap(1,3)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 13, "result": "RE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1)[::-1]:\n            qc.cp(2*pi/(2**(n-j-i)), n-j-1, i)\n    for i in range(n//2):\n        qc.swap(i,n-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 14, "result": "RE", "execution_time": "1223 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n-i-1)[::-1]:\n            qc.cp(2*pi/(2**(n-j-i)), i, n-j-1)\n    for i in range(n//2):\n        qc.swap(i,n-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 15, "result": "RE", "execution_time": "1158 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)[::-1]:\n        qc.h(i)\n        for j in range(i):\n            qc.cp(2*pi/(2**(j+2)), i, i - j - 1)\n    for i in range(n//2):\n        qc.swap(i,n-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AC7DD7ABB5214", "submission_order": 16, "result": "AC", "execution_time": "1750 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)[::-1]:\n        qc.h(i)\n        for j in range(i):\n            qc.cp(2*pi/(2**(j+2)), i, i - j - 1)\n    for i in range(n//2):\n        qc.swap(i,n-i-1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AD1A97A0D5816", "submission_order": 1, "result": "WA", "execution_time": "1258 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n-1-i)\n        for j in range(n-i-1):\n            qc.cp(2*math.pi/(2**(n-i-j)),j , n-1-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AD1A97A0D5816", "submission_order": 2, "result": "DLE", "execution_time": "1207 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n-1-i)\n        for j in range(n-i-1):\n            qc.cp(2*math.pi/(2**(n-i-j)),j , n-1-i)\n    for i in range(int((n)/2)):\n        qc.cx(i,n-1-i)\n        qc.cx(n-1-i,i)\n        qc.cx(i,n-1-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AD1A97A0D5816", "submission_order": 3, "result": "DLE", "execution_time": "1402 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n-1-i)\n        for j in range(n-i-1):\n            qc.cp(2*math.pi/(2**(n-i-j)),j , n-1-i)\n    for i in range(int((n)/2)):\n        qc.swap(i,n-1-i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AD5B97C1952DB", "submission_order": 1, "result": "RE", "execution_time": "1061 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      for j in range(n-i):\n        if j == 0:\n          qc.h(i)\n        else:\n          qc.cp(2*np.pi/2**(j+1), j+i, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AD5B97C1952DB", "submission_order": 2, "result": "WA", "execution_time": "1176 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      for j in range(n-i):\n        if j == 0:\n          qc.h(i)\n        else:\n          qc.cp(2*np.pi/2**(j+1), j+i, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AD5B97C1952DB", "submission_order": 3, "result": "WA", "execution_time": "1244 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      for j in range(n-i):\n        if j == 0:\n          qc.h(i)\n        else:\n          qc.cp(2*np.pi/2**(j+1), j+i, i)\n\n    for i in range(n//2):\n      qc.swap(i, n-i-1)\n      \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AD5B97C1952DB", "submission_order": 4, "result": "WA", "execution_time": "1203 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # for i in range(n):\n    #   for j in range(n-i):\n    #     if j == 0:\n    #       qc.h(i)\n    #     else:\n    #       qc.cp(2*np.pi/2**(j+1), i+j, i)\n    for i in range(n):\n      qc.h(-1-i)\n      for j in range(i+1,n):\n          qc.cp(2 * np.pi / 2**(j+1-i), -1-j, -1-i)\n\n    # for i in range(n//2):\n    #   qc.swap(i, n-i-1)\n      \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AD5B97C1952DB", "submission_order": 5, "result": "AC", "execution_time": "1716 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(-1-i)\n      for j in range(i+1,n):\n          qc.cp(2 * np.pi / 2**(j+1-i), -1-j, -1-i)\n\n    for i in range(n//2):\n      qc.swap(i, n-i-1)\n      \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ADB6050674B8E", "submission_order": 1, "result": "WA", "execution_time": "1573 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(2*math.pi*(i-j),j,i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ADB6050674B8E", "submission_order": 2, "result": "WA", "execution_time": "1549 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(2*math.pi*(i-j),j,i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "ADB6050674B8E", "submission_order": 3, "result": "AC", "execution_time": "1572 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi/2**(i-j),j,i)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE0379C4F0AC7", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap_gate(qc, i, j):\n        qc.cx(i,j)\n        qc.cx(j,i)\n        qc.cx(i,j)\n        return qc\n    def qft_layer(qc, i):\n        qc.h(i)\n        for l in range(i):\n            k = i - 1 - l\n            theta = 2 * math.pi / 2 ** (i - k + 1)\n            qc.cp(theta, k, i)\n        return qc\n    for j in range(n):\n        qc = qft_layer(qc, n - 1 - j)\n    half = n//2\n    for i in range(half):\n        qc = swap_gate(qc, i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE0379C4F0AC7", "submission_order": 2, "result": "AC", "execution_time": "1737 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap_gate(qc, i, j):\n        qc.cx(i,j)\n        qc.cx(j,i)\n        qc.cx(i,j)\n        return qc\n    def qft_layer(qc, i):\n        qc.h(i)\n        for l in range(i):\n            k = i - 1 - l\n            theta = 2 * math.pi / 2 ** (i - k + 1)\n            qc.cp(theta, k, i)\n        return qc\n    for j in range(n):\n        qc = qft_layer(qc, n - 1 - j)\n    half = n//2\n    for i in range(half):\n        qc = swap_gate(qc, i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE3A78CCAB916", "submission_order": 1, "result": "WA", "execution_time": "1149 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(pi / (2 ** (j - i)), j, i)\n    \n    # Reverse the qubit order\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE3A78CCAB916", "submission_order": 2, "result": "WA", "execution_time": "1119 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n     # Implement the QFT in little-endian order\n    for i in range(n):\n        # Apply Hadamard gate to qubit i\n        qc.h(i)\n        \n        # Apply the controlled phase rotations\n        for j in range(i+1, n):\n            qc.cp(pi / (2 ** (j - i)), j, i)\n    \n    # Reverse the qubit order\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE3A78CCAB916", "submission_order": 3, "result": "WA", "execution_time": "1104 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n = 2\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(pi / (2 ** (j - i)), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE3A78CCAB916", "submission_order": 4, "result": "RE", "execution_time": "1562 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n = 2\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(pi / (2 ** (j - i)), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE3A78CCAB916", "submission_order": 5, "result": "RE", "execution_time": "1299 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply the QFT\n    for qubit in range(n):\n        # Apply the Hadamard gate\n        qc.h(qubit)\n        # Apply the controlled phase shift gates\n        for k in range(2, n - qubit + 1):\n            qc.cp(np.pi / (2 ** (k-1)), qubit, qubit + k - 1)\n\n    # Swap qubits to reverse the bit order\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE3A78CCAB916", "submission_order": 6, "result": "RE", "execution_time": "1092 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply the QFT\n    for qubit in range(n):\n        # Apply the Hadamard gate\n        qc.h(qubit)\n        # Apply the controlled phase shift gates\n        for k in range(2, n - qubit + 1):\n            qc.cp(np.pi / (2 ** (k-1)), qubit, qubit + k - 1)\n\n    # Swap qubits to reverse the bit order\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE42E00A249FA", "submission_order": 1, "result": "WA", "execution_time": "1320 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply controlled rotation gates\n    for i in range(n):\n        for j in range(i):\n            k = i - j + 1\n            qc.cp(2 * pi / 2**k, j, i)\n    \n    # Swap qubits to correct the order (little-endian)\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE42E00A249FA", "submission_order": 2, "result": "WA", "execution_time": "1296 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Implement QFT\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            qc.cp(pi / 2**(j - i), j, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE42E00A249FA", "submission_order": 3, "result": "DLE", "execution_time": "1395 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n \ndef qft_rotations(qc, n):\n    \"\"\"Apply the QFT to the first n qubits in the quantum circuit qc.\"\"\"\n    if n == 0:\n        return qc\n    n -= 1\n    qc.h(n)\n    for qubit in range(n):\n        qc.cp(np.pi / 2**(n-qubit), qubit, n)\n    qft_rotations(qc, n)\n\ndef swap_registers(qc, n):\n    \"\"\"Swap the qubits to reverse their order.\"\"\"\n    for qubit in range(n//2):\n        qc.swap(qubit, n-qubit-1)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the QFT\n    qft_rotations(qc, n)\n    \n    # Reverse the order of qubits by swapping them\n    swap_registers(qc, n)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE42E00A249FA", "submission_order": 4, "result": "WA", "execution_time": "1529 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef qft_rotations_optimized(qc, n):\n    \"\"\"Apply the QFT to the first n qubits in the quantum circuit qc.\"\"\"\n    for j in range(n):\n        qc.h(j)\n        for k in range(j+1, n):\n            qc.cp(np.pi / 2**(k-j), k, j)\n\ndef swap_registers_optimized(qc, n):\n    \"\"\"Swap the qubits to reverse their order.\"\"\"\n    for qubit in range(n//2):\n        qc.swap(qubit, n-qubit-1)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the optimized QFT rotations\n    qft_rotations_optimized(qc, n)\n    \n    # Reverse the order of qubits by swapping them\n    swap_registers_optimized(qc, n)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE42E00A249FA", "submission_order": 5, "result": "WA", "execution_time": "1051 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the QFT\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(np.pi / 2**(j-i), j, i)\n    \n    # Reverse the order of qubits by swapping them\n    for i in range(n // 2):\n        qc.swap(i, n-i-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE42E00A249FA", "submission_order": 6, "result": "WA", "execution_time": "1089 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the QFT\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(np.pi / 2**(j-i), j, i)\n    \n    # Reverse the order of qubits by swapping them\n    for i in range(n // 2):\n        qc.swap(i, n-i-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE42E00A249FA", "submission_order": 7, "result": "WA", "execution_time": "1327 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the QFT\n    for i in range(n):\n        qc.h(i)  # Apply Hadamard gate to qubit i\n        for j in range(i+1, n):\n            # Apply controlled phase rotation (CP) with decreasing angles\n            qc.cp(np.pi / 2**(j-i), j, i)\n    \n    # Reverse the order of qubits by swapping them\n    for i in range(n // 2):\n        qc.swap(i, n-i-1)\n    \n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 1, "result": "WA", "execution_time": "1824 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n\n  for i in range(n):\n    qc.h(i)\n    for j in range(2, n - i + 1):\n      qc.cp(2 * math.pi / pow(2, j), i + j - 1, i)\n  return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 2, "result": "RE", "execution_time": "1545 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int]) -> QuantumCircuit:\n  n = len(idx)\n  for j in range(n):\n    qc.h(idx[j])\n    for k in range(j+1, n):\n      theta = math.pi / (2 ** (k - j))\n      qc.cp(theta, idx[k], idx[j])\n\n  for i in range(n // 2):\n    qc.swap(idx[i], idx[n - i - 1])\n\n  return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    QFT(qc, list(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 3, "result": "RE", "execution_time": "1446 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int]) -> QuantumCircuit:\n    n = len(idx)\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            qc.cp(theta, idx[k], idx[j])\n\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    QFT(qc, list(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 4, "result": "RE", "execution_time": "1692 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int]) -> QuantumCircuit:\n    n = len(idx)\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            qc.cp(theta, idx[k], idx[j])\n\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    QFT(qc, list(n))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 5, "result": "WA", "execution_time": "1518 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int]) -> QuantumCircuit:\n    n = len(idx)\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            qc.cp(theta, idx[k], idx[j])\n\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    QFT(qc, list(range(n)))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 6, "result": "WA", "execution_time": "1741 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int]) -> QuantumCircuit:\n    n = len(idx)\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = 2 * math.pi / (2 ** (k - j))\n            qc.cp(theta, idx[k], idx[j])\n\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    QFT(qc, list(range(n)))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 7, "result": "WA", "execution_time": "1844 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int]) -> QuantumCircuit:\n    n = len(idx)\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = 2 * math.pi / (2 ** (k - j + 1))\n            qc.cp(theta, idx[k], idx[j])\n\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    QFT(qc, list(range(n)))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 8, "result": "RE", "execution_time": "1711 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int]) -> QuantumCircuit:\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    \n    n = len(idx)\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    QFT(qc, list(range(n)))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AE51AAF8D1287", "submission_order": 9, "result": "AC", "execution_time": "1771 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int]) -> QuantumCircuit:\n    n = len(idx)\n    \n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    \n    \n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    QFT(qc, list(range(n)))\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEB363CF61CD3", "submission_order": 1, "result": "RE", "execution_time": "1059 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, j):\n            theta = 2 * math.pi / (2 ** (j - i + 1))\n            qc.cp(j, i)\n\n    # swap\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEB363CF61CD3", "submission_order": 2, "result": "WA", "execution_time": "1071 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            theta = 2 * math.pi / (2 ** (j - i + 1))\n            qc.cp(theta, j, i)\n\n    # swap\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEB363CF61CD3", "submission_order": 3, "result": "AC", "execution_time": "1907 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(n - 1 - i)\n        for j in range(i + 1, n):\n            theta = 2 * math.pi / (2 ** (j - i + 1))\n            qc.cp(theta, n - 1 - j, n - 1 - i)\n\n    # swap\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEBB62641F6D1", "submission_order": 1, "result": "RE", "execution_time": "2519 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.QFT(n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEBB62641F6D1", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.QFT(n)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 1, "result": "RE", "execution_time": "1146 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_com(i):\n        qc.h(i)\n        for j in range(n - 1 - i):\n            qc.cp((np.pi / 2 **(j + 1)), i + j + 1, i)\n    for i in range(n):\n        qft_com(i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 2, "result": "RE", "execution_time": "1303 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n - 1 - i):\n            qc.cp((np.pi / (2 ** (j + 1))), i + j + 1, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 3, "result": "WA", "execution_time": "1162 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n - 1 - i):\n            qc.cp((np.pi / (2 ** (j + 1))), i + j + 1, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 4, "result": "WA", "execution_time": "1215 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(n - 1 - i):\n            qc.cp((np.pi / (2 ** (j + 1))), i, i + j + 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 5, "result": "WA", "execution_time": "1297 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_com(i):\n        qc.h(i)\n        for j in range(n - 1 - i):\n            qc.cp((np.pi / 2 **(j + 1)), i + j + 1, i)\n    for i in range(n):\n        qft_com(i)\n    for i in range(n // 2):\n        qc.cx(i, n - 1 - i)\n        qc.cx(n - 1 - i, i)\n        qc.cx(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 6, "result": "WA", "execution_time": "1110 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_com(i):\n        qc.h(i)\n        for j in range(n - 1 - i):\n            qc.cp(np.pi / (2 **(j + 1)), i + j + 1, i)\n    for i in range(n):\n        qft_com(i)\n    for i in range(n // 2):\n        qc.cx(i, n - 1 - i)\n        qc.cx(n - 1 - i, i)\n        qc.cx(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 7, "result": "RE", "execution_time": "1363 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_rotations(circuit, m):\n        if m == 0:\n            return circuit\n        m -= 1\n        circuit.h(n)\n        for qubit in range(n):\n            circuit.cp(pi/2**(n-qubit), qubit, m)\n        qft_rotations(circuit, m)\n    qft_rotations(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 8, "result": "RE", "execution_time": "1059 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_rotations(circuit, m):\n        if m == 0:\n            return circuit\n        m -= 1\n        circuit.h(m)\n        for qubit in range(m):\n            circuit.cp(pi/2**(m-qubit), qubit, m)\n        qft_rotations(circuit, m)\n    qft_rotations(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 9, "result": "WA", "execution_time": "1148 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_rotations(circuit, m):\n        if m == 0:\n            return circuit\n        m -= 1\n        circuit.h(m)\n        for qubit in range(m):\n            circuit.cp(np.pi/2**(-qubit), qubit, m)\n        qft_rotations(circuit, m)\n    qft_rotations(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 10, "result": "WA", "execution_time": "1123 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def qft_rotations(circuit, m):\n        if m == 0:\n            return circuit\n        m -= 1\n        circuit.h(m)\n        for qubit in range(m):\n            circuit.cp(np.pi/2**(-qubit), qubit, m)\n        qft_rotations(circuit, m)\n    def swap_registers(circuit, m):\n        for qubit in range(m//2):\n            circuit.swap(qubit, m-qubit-1)\n        return circuit\n    qft_rotations(qc, n)\n    swap_registers(qc, n)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AEFFEDDFA1FD1", "submission_order": 11, "result": "AC", "execution_time": "1750 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for itarg in range(n - 1, -1, -1):\n        qc.h(itarg)\n        for ictrl in range(itarg - 1, -1, -1):\n            power = ictrl - itarg - 1 + n\n            qc.cp((2 ** power) * 2. * np.pi / (2 ** n), ictrl, itarg)\n\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF5F74797E4E9", "submission_order": 1, "result": "RE", "execution_time": "1404 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for k in range(i + 1, n):\n            qc.append(PhaseGate(np.pi / (2 ** (k - i))).control(1), [k, i])\n    qc.swap(0, n - 1)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF5F74797E4E9", "submission_order": 2, "result": "WA", "execution_time": "1116 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        qc.h(0)\n        return qc\n    for i in range(n):\n        qc.h(i)\n        for k in range(i + 1, n):\n            qc.append(PhaseGate(np.pi / (2 ** (k - i))).control(1), [k, i])\n    qc.swap(0, n - 1)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF7BCF38BE080", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qft = QFT(num_qubits=n).to_gate()\n    qc.append(qft, qargs=list(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 1, "result": "WA", "execution_time": "1751 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j - 1))\n            qc.crz(phase / 2, i, j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 2, "result": "WA", "execution_time": "1591 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j + 1))\n            qc.crz(phase / 2, i, j)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 3, "result": "WA", "execution_time": "1219 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j + 1))\n            qc.crz(phase / 2, j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 4, "result": "WA", "execution_time": "1296 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j + 1))\n            qc.crz(- phase / 2, j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 5, "result": "WA", "execution_time": "1406 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j - i + 1))\n            qc.crz(phase / 2, j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 6, "result": "WA", "execution_time": "1300 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j - i + 1))\n            qc.crz(phase, j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 7, "result": "WA", "execution_time": "1686 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j - i + 1))\n            qc.cp(phase , j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 8, "result": "WA", "execution_time": "1650 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j - i + 1))\n            qc.crz(phase , j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 9, "result": "WA", "execution_time": "1582 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j - i + 1))\n            qc.cp(phase , j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 10, "result": "WA", "execution_time": "1504 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = pi / (2 ** (j - i))\n            qc.cp(phase, j, i)  # Controlled phase gate\n    qc.barrier()\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)  # Swap to reverse the order\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 11, "result": "WA", "execution_time": "1602 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = pi / (2 ** (j - i))\n            qc.cp(phase, j, i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 12, "result": "WA", "execution_time": "1419 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            phase = 2 * pi / (2 ** (j - i + 1))\n            qc.crz(phase, j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 13, "result": "WA", "execution_time": "1516 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    # Write your code here:\n    qc = qft(n, True)\n    return qc\n\n\ndef qft(n: int, is_little_endian: bool = False):\n    qc = QuantumCircuit(n)\n    targets = range(n) if not is_little_endian else reversed(range(n))\n    for i in targets:\n        qc.h(i)\n        controls = range(i + 1, n) if not is_little_endian else reversed(range(i + 1, n, 1))\n        for j in controls:\n            phase = 2 * pi / (2 ** (j - i + 1))\n            qc.crz(phase, j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 14, "result": "WA", "execution_time": "1513 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    # Write your code here:\n    qc = qft(n, True)\n    return qc\n\n\ndef qft(n: int, is_little_endian: bool = False):\n    qc = QuantumCircuit(n)\n    targets = range(n) if not is_little_endian else reversed(range(n))\n    for i in targets:\n        qc.h(i)\n        controls = range(i + 1, n) if not is_little_endian else reversed(range(i))\n        for j in controls:\n            phase = 2 * pi / (2 ** (abs(j - i) + 1))\n            qc.crz(phase, j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AF87D2595D72C", "submission_order": 15, "result": "AC", "execution_time": "1869 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    # Write your code here:\n    qc = qft(n, True)\n    return qc\n\n\ndef qft(n: int, is_little_endian: bool = False):\n    qc = QuantumCircuit(n)\n    targets = range(n) if not is_little_endian else reversed(range(n))\n    for i in targets:\n        qc.h(i)\n        controls = range(i + 1, n) if not is_little_endian else reversed(range(i))\n        for j in controls:\n            phase = 2 * pi / (2 ** (abs(j - i) + 1))\n            qc.cp(phase, j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AFBEBC7EF76AC", "submission_order": 1, "result": "WA", "execution_time": "1082 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        for k in range(j):\n            qc.cp(pi/2**(j-k), k, j)\n        qc.h(j)\n    \n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC002_B4", "user": "AFBEBC7EF76AC", "submission_order": 2, "result": "WA", "execution_time": "1394 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n-1, -1, -1):\n        qc.h(j)\n        for k in range(j-1, -1, -1):\n            qc.cp(pi/2**(j-k), k, j)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A04177BF589F8", "submission_order": 1, "result": "AC", "execution_time": "2108 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate\n\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2 * math.pi * S[i] / 2 ** m, i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2, 2, [1, 3])\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     sv = Statevector.from_label('11')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC002_B5", "user": "A044DBDEDB487", "submission_order": 1, "result": "AC", "execution_time": "2047 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef f(x, S):\n    pass\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for (i, s) in zip(range(n), S):\n        qc.p(2*pi *s/ (2**m), i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0A2C9525EEEC", "submission_order": 1, "result": "AC", "execution_time": "2054 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import tau\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i, s in enumerate(S):\n        qc.p(tau * s / (1 << m), i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0A8A23BED7F4", "submission_order": 1, "result": "WA", "execution_time": "1561 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * S[i]\n        qc.p(theta, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0A8A23BED7F4", "submission_order": 2, "result": "WA", "execution_time": "1615 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * S[i] / (2 ** n)\n        qc.p(theta, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0A8A23BED7F4", "submission_order": 3, "result": "AC", "execution_time": "2011 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * S[i] / (2 ** m)\n        qc.p(theta, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0C6AC5D26EAC", "submission_order": 1, "result": "RE", "execution_time": "1494 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.cp(2.0*np.pi/(2.0**m)*S[i])\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0C6AC5D26EAC", "submission_order": 2, "result": "AC", "execution_time": "2009 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.p(2.0*np.pi/(2.0**m)*S[i], i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0DE0DBD2182F", "submission_order": 1, "result": "RE", "execution_time": "1081 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if S[i] == 1:\n            qc.p(2*math.pi/(1<<(m-i)) , i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0DE0DBD2182F", "submission_order": 2, "result": "RE", "execution_time": "1449 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(len(S)):\n        if S[i] == 1:\n            qc.p(2*math.pi/(1<<(m-i)) , i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0DE0DBD2182F", "submission_order": 3, "result": "AC", "execution_time": "2272 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(len(S)):\n        qc.p(2*math.pi*S[i]/(1<<m) , i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0EF95FB76DF1", "submission_order": 1, "result": "RE", "execution_time": "1287 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Implement the phase oracle\n    for x in range(2**n):\n        # Convert x to its binary representation\n        bin_x = [int(bit) for bit in bin(x)[2:].zfill(n)]\n        \n        # Compute f(x)\n        f_x = sum(S[i] * bin_x[i] for i in range(n))\n        \n        # Calculate the phase angle\n        angle = (2 * pi * f_x) / (2 ** m)\n        \n        # Apply the phase shift to the state |x>\n        for i in range(n):\n            if bin_x[i] == 1:\n                qc.rz(angle, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0EF95FB76DF1", "submission_order": 2, "result": "RE", "execution_time": "1368 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Implement the phase oracle\n    for x in range(2**n):\n        # Convert x to its binary representation\n        bin_x = [int(bit) for bit in bin(x)[2:].zfill(n)]\n        \n        # Compute f(x)\n        f_x = sum(S[i] * bin_x[i] for i in range(n))\n        \n        # Calculate the phase angle\n        angle = (2 * pi * f_x) / (2 ** m)\n        \n        # Apply the phase shift to the correct state\n        for i in range(n):\n            if bin_x[i] == 1:\n                qc.x(i)  # Apply X gate to flip qubit if necessary\n        \n        qc.mcx(list(range(n)), 0)  # Apply multi-controlled Z gate\n        qc.rz(angle, 0)  # Apply the phase shift\n        qc.mcx(list(range(n)), 0)  # Reverse the multi-controlled Z gate\n\n        for i in range(n):\n            if bin_x[i] == 1:\n                qc.x(i)  # Revert the X gate if it was applied earlier\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A0EF95FB76DF1", "submission_order": 3, "result": "AC", "execution_time": "1890 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2.0*np.pi/(2.0**m)*S[i], i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 1, "result": "RE", "execution_time": "1247 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.p(2 * math.pi * s[i] / pow(2, m), i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 2, "result": "WA", "execution_time": "1198 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 3, "result": "RE", "execution_time": "1235 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.p(2 * math.pi * s[i] / pow(2, m), i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 4, "result": "RE", "execution_time": "1336 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.phase(2 * math.pi * s[i] / pow(2, m), i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 5, "result": "RE", "execution_time": "1023 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.phas(2 * pi * s[i] / pow(2, m), i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 6, "result": "RE", "execution_time": "1336 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.phase(0, i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 7, "result": "RE", "execution_time": "1185 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.phase(0, i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 8, "result": "WA", "execution_time": "1271 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.p(2 * math.pi / pow(2, m), i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 9, "result": "RE", "execution_time": "1280 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.p(2 * math.pi * s[i] / pow(2, m), i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 10, "result": "RE", "execution_time": "1123 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.p(2 * math.pi * float(s[i]) / pow(2, m), i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A13DE5922F58E", "submission_order": 11, "result": "AC", "execution_time": "2695 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.p(2 * math.pi * S[i] / pow(2, m), i)\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A151DEBE79438", "submission_order": 1, "result": "AC", "execution_time": "2106 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for idx in range(0, n):\n        theta = 2 * math.pi * S[idx] / (2**m)\n        qc.p(theta, idx)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A19D045C5FE20", "submission_order": 1, "result": "WA", "execution_time": "1166 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.p(math.pi * S[i] / 2**m, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A19D045C5FE20", "submission_order": 2, "result": "AC", "execution_time": "1974 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.p(2 * math.pi * S[i] / 2**m, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A1C9CB2896064", "submission_order": 1, "result": "AC", "execution_time": "2449 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2 * math.pi * S[i] / 2 ** m, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A1E9E32F9CAB5", "submission_order": 1, "result": "WA", "execution_time": "2180 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A222D01B42E79", "submission_order": 1, "result": "RE", "execution_time": "1853 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i]/(2**m))\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B5", "user": "A222D01B42E79", "submission_order": 2, "result": "AC", "execution_time": "2080 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i]/(2**m), i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B5", "user": "A266BB9DB3C1D", "submission_order": 1, "result": "RE", "execution_time": "1672 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.p(2*np.pi*S[i]/2**m, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A266BB9DB3C1D", "submission_order": 2, "result": "AC", "execution_time": "2760 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.p(2*np.pi*S[i]/2**m, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A36B1ED26740B", "submission_order": 1, "result": "AC", "execution_time": "2507 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.append(U1Gate(2 * pi * S[i] / 2 ** m), [i])\n \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A3F3645C74CF0", "submission_order": 1, "result": "RE", "execution_time": "1238 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # For each qubit i, apply a controlled phase rotation\n    for i in range(n):\n        angle = 2 * pi * S[i] / (2 ** m)\n        qc.cp(angle, i, 0)  # Controlled phase rotation with qubit i controlling\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A3FC3048CD1D7", "submission_order": 1, "result": "AC", "execution_time": "2310 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i]/2**m,i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A4C925003499B", "submission_order": 1, "result": "WA", "execution_time": "1270 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.p(S[i]/(2**m), i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A4C925003499B", "submission_order": 2, "result": "AC", "execution_time": "1911 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.p(2*math.pi*S[i]/(2**m), i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A55FB7A02A342", "submission_order": 1, "result": "RE", "execution_time": "1156 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n, name='oracle')\n    # Write your code here:\n    control_qubits = list(range(n))\n    \n    # Iterate through each qubit and apply controlled phase rotations\n    for i in range(n):\n        phase = 2 * np.pi * S[i] / (2 ** m)\n        qc.cp(phase, control_qubits[i], n)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A5A2D9B1DC196", "submission_order": 1, "result": "AC", "execution_time": "1977 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n\n    for i in range(n):\n        qc.p(S[i] * 2 * math.pi / 2**m, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A5A30757D0C26", "submission_order": 1, "result": "RE", "execution_time": "1461 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import MCPhaseGate\n#from qiskit.quantum_info import Statevector\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.x(1)\n    # Write your code here:\n    if n==1:\n        qc.p(2*np.pi*S[0]/(2**m),0)\n        return qc\n    for i in range(n):\n        qc.cp(2*np.pi*S[i]/(2**m),i,(i+1)%n)\n\n \n    return qc\n\n\nqc = solve(2,2,[1,3])\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_B5", "user": "A5A30757D0C26", "submission_order": 2, "result": "WA", "execution_time": "1411 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import MCPhaseGate\n#from qiskit.quantum_info import Statevector\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    if n==1:\n        qc.p(2*np.pi*S[0]/(2**m),0)\n        return qc\n    for i in range(n):\n        qc.cp(2*np.pi*S[i]/(2**m),i,(i+1)%n)\n\n \n    return qc\n\n\nqc = solve(2,2,[1,3])\nprint(qc)\n#print(Statevector(qc)) #こことimportを消す\n'''"}
{"problem": "QPC002_B5", "user": "A5A30757D0C26", "submission_order": 3, "result": "AC", "execution_time": "2353 ms", "memory": "161 MiB", "code": "'''python\nfrom math import tau  # tau = 2π\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    \"\"\"\n    Return an n-qubit oracle O such that\n        |x> ──►  exp(2πi f(x)/2^m) |x>,\n    with  f(x) = Σ S_k x_k  (little-endian).\n    Circuit depth = 1 (all gates parallel).\n    \"\"\"\n    qc = QuantumCircuit(n)\n\n    denom = 1 << m          # 2^m\n    for k in range(n):\n        # Phase angle ϕ_k = 2π S_k / 2^m  (wrapped automatically by Qiskit)\n        phi = tau * (S[k] % denom) / denom\n        qc.p(phi, k)        # Phase (diag[1, e^{iϕ_k}]) on qubit k\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A5AE42EE5763C", "submission_order": 1, "result": "WA", "execution_time": "1154 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n):\n    qc.p(math.pi * S[i] / pow(2, m), i)\n  return qc\n'''"}
{"problem": "QPC002_B5", "user": "A5AE42EE5763C", "submission_order": 2, "result": "AC", "execution_time": "2092 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(n):\n    qc.p(2 * math.pi * S[i] / pow(2, m), i)\n  return qc\n'''"}
{"problem": "QPC002_B5", "user": "A6E62382E7A2B", "submission_order": 1, "result": "RE", "execution_time": "1945 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef create_oracle(n, m, S):\n    # Create a quantum circuit with n qubits\n    qc = QuantumCircuit(n)\n    \n    # Iterate over all possible values of x from 0 to 2^n - 1\n    for x in range(2**n):\n        # Calculate f(x)\n        f_x = sum(S[i] * ((x >> i) & 1) for i in range(n))\n        \n        # Calculate the phase\n        phase = (2 * math.pi * f_x) / (2**m)\n        \n        # Apply the phase shift to the corresponding state |x>\n        if phase != 0:\n            qc.p(phase, x)  # Apply phase shift using the p gate\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A6E62382E7A2B", "submission_order": 2, "result": "RE", "execution_time": "2082 ms", "memory": "157 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef create_oracle(n, m, S):\n    # Create a quantum register and a quantum circuit\n    qr = QuantumRegister(n)\n    qc = QuantumCircuit(qr)\n\n    # Iterate over all possible values of x (0 to 2^n - 1)\n    for x in range(2**n):\n        # Calculate f(x)\n        f_x = sum(S[i] * ((x >> i) & 1) for i in range(n))\n        \n        # Calculate the phase\n        phase = (2 * math.pi * f_x) / (2**m)\n        \n        # Apply the phase shift to the state |x>\n        qc.p(phase, qr[0])  # Apply phase to the first qubit (little-endian)\n        for i in range(1, n):\n            qc.p(phase, qr[i])  # Apply phase to the remaining qubits\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A6F060F6D6BD4", "submission_order": 1, "result": "RE", "execution_time": "1150 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2. * np.pi / (2 ** m) * S[i], i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A6F060F6D6BD4", "submission_order": 2, "result": "AC", "execution_time": "2597 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2. * np.pi / (2 ** m) * S[i], i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A760E2B00CF6F", "submission_order": 1, "result": "WA", "execution_time": "1674 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i, s in enumerate(S):\n        angle = 2 * pi / 2 ** m\n        qc.rz(angle / 2, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A760E2B00CF6F", "submission_order": 2, "result": "WA", "execution_time": "1234 ms", "memory": "154 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i, s in enumerate(S):\n        if s == 1:\n            qc.x(i)\n        angle = 2 * pi / 2 ** m\n        qc.rz(angle / 2, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A760E2B00CF6F", "submission_order": 3, "result": "WA", "execution_time": "1452 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i, s in enumerate(S):\n        if s == 1:\n            qc.x(i)\n        angle = 2 * pi / 2 ** m\n        qc.rz(angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A760E2B00CF6F", "submission_order": 4, "result": "WA", "execution_time": "1366 ms", "memory": "156 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i, s in enumerate(S):\n        angle = 2 * pi * s / 2 ** m\n        if s == 1:\n            qc.x(i)\n        qc.p(angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A760E2B00CF6F", "submission_order": 5, "result": "AC", "execution_time": "2071 ms", "memory": "156 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i, s in enumerate(S):\n        angle = 2 * pi * s / 2 ** m\n        qc.p(angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A8044CD175B59", "submission_order": 1, "result": "WA", "execution_time": "1450 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate,PhaseGate\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for l in range(2**n):\n        theta = 0\n        for i in range(n):\n            # check if i-th bit of l is 0 or 1\n            if not ((l >> i) & 1):\n                qc.x(i)\n            else:\n                theta += (1<<i)*S[i]\n        if n == 1:\n            qc.p(math.pi * theta / 2**m,0)\n        else:\n            # apply multiple controlled Z gate\n            qc.append(PhaseGate(theta=math.pi * theta/(2**m)).control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A8044CD175B59", "submission_order": 2, "result": "AC", "execution_time": "2232 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate,XGate\nimport math\n \ndef solve(n: int, m:int, S:list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(S[i] * 2 * math.pi / 2 ** m,i)\n\n    return qc\n\n# for n in range(5):\n#     for l in range(2**(n+1)):\n#         print(f\"{n+1} {l+1}\")\n#         solve(n+1,l+1)\n'''"}
{"problem": "QPC002_B5", "user": "A88554730A452", "submission_order": 1, "result": "AC", "execution_time": "2655 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*np.pi*S[i]/2**m, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A887EF4D7090A", "submission_order": 1, "result": "RE", "execution_time": "1346 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cp(2 * np.pi / (2 ** m), i) \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A887EF4D7090A", "submission_order": 2, "result": "RE", "execution_time": "1417 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if S[i] != 0:\n            phase_shift = 2 * np.pi * S[i] / (2 ** m)\n            qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A887EF4D7090A", "submission_order": 3, "result": "RE", "execution_time": "1214 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if(i==0):\n            continue\n        if S[i] != 0:\n            phase_shift = 2 * np.pi * S[i] / (2 ** m)\n            qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A887EF4D7090A", "submission_order": 4, "result": "RE", "execution_time": "1125 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if(i==0):\n            continue\n        if S[i] != 0:\n            phase_shift = 2 * math.pi * S[i] / (2 ** m)\n            qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A887EF4D7090A", "submission_order": 5, "result": "WA", "execution_time": "1493 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if(i==0):\n            continue\n        if S[i] != 0:\n            phase_shift = 2 * 3.141592 * S[i] / (2 ** m)\n            qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A887EF4D7090A", "submission_order": 6, "result": "WA", "execution_time": "1397 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if(i==0):\n            continue\n        if S[i] != 0:\n            phase_shift = 2 * math.pi * S[i] / (2 ** m)\n            qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A887EF4D7090A", "submission_order": 7, "result": "AC", "execution_time": "2014 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if S[i] != 0:\n            phase_shift = 2 * 3.141592 * S[i] / (2 ** m)\n            qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A8E2BBFB3AAE9", "submission_order": 1, "result": "AC", "execution_time": "2167 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n, m, s) -> QuantumCircuit:\n\tfrom numpy import pi\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.p(pi * s[i] / 2**(m - 1), i)\n\treturn qc\n'''"}
{"problem": "QPC002_B5", "user": "A9033B76F8EC4", "submission_order": 1, "result": "AC", "execution_time": "2366 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        angle = 2 * pi * S[i] / (2**m)\n        qc.p(angle, i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A90D303846997", "submission_order": 1, "result": "RE", "execution_time": "1340 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nfrom math import pi\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x([0, 1])\n    # Write your code here:\n\n    if n == 1:\n        theta = 2 * pi * S[0] / (2 ** m)\n        qc.p(theta, 0)\n    else:\n        for i in range(n):\n            theta = 2 * pi * S[i] / (2 ** m)\n            qc.p(theta, i)\n            # mp = PhaseGate(theta).control(2)\n            # qc.append(mp, range(n))\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A90D303846997", "submission_order": 2, "result": "AC", "execution_time": "2270 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.circuit.library import PhaseGate\nfrom math import pi\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.x([0, 1])\n    # Write your code here:\n\n    if n == 1:\n        theta = 2 * pi * S[0] / (2 ** m)\n        qc.p(theta, 0)\n    else:\n        for i in range(n):\n            theta = 2 * pi * S[i] / (2 ** m)\n            qc.p(theta, i)\n            # mp = PhaseGate(theta).control(2)\n            # qc.append(mp, range(n))\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A929DDB0B4A4C", "submission_order": 1, "result": "AC", "execution_time": "2027 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.p(2 * pi * S[i] / 2 ** m, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A962B2AC18595", "submission_order": 1, "result": "RE", "execution_time": "1218 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2.0*np.pi/(2.0**m)*S[i], i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A962B2AC18595", "submission_order": 2, "result": "AC", "execution_time": "2122 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2.0*np.pi/(2.0**m)*S[i], i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A97272D97D461", "submission_order": 1, "result": "RE", "execution_time": "1706 ms", "memory": "150 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for k in range(n):\n        theta = 2*math.pi()*S[k]//2**m\n        qc.p(theta,k)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A97272D97D461", "submission_order": 2, "result": "RE", "execution_time": "1550 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for k in range(n):\n        theta = 2*math.pi*S[k]//2**m\n        qc.p(theta,k)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A97272D97D461", "submission_order": 3, "result": "AC", "execution_time": "1899 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for k in range(n):\n        theta = 2*math.pi*S[k]/2**m\n        qc.p(theta,k)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A9839A6D299F5", "submission_order": 1, "result": "WA", "execution_time": "1420 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        angle = 2 * np.pi * S[i]\n        qc.p(angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A9839A6D299F5", "submission_order": 2, "result": "RE", "execution_time": "1321 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        angle = 2 * np.pi * S[i] / 2**m\n        qc.p(angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "A9839A6D299F5", "submission_order": 3, "result": "AC", "execution_time": "1818 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        angle = 2 * np.pi * S[i] / 2**m\n        qc.p(angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AA4AD89664AA9", "submission_order": 1, "result": "RE", "execution_time": "1904 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(1)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i]/(1<<m), i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AA4AD89664AA9", "submission_order": 2, "result": "AC", "execution_time": "2032 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i]/(1<<m), i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AA588D4784175", "submission_order": 1, "result": "RE", "execution_time": "1150 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    phase_factor = 2.0*np.pi/(2.0**m)\n    for i,s in enumerate(s):\n        qc.p(phase_factor*s, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AA588D4784175", "submission_order": 2, "result": "RE", "execution_time": "1398 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    phase_factor = 2.0*np.pi/(2.0**m)\n    for i,s in enumerate(s):\n        qc.p(phase_factor*s, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AA588D4784175", "submission_order": 3, "result": "AC", "execution_time": "1704 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    phase_factor = 2.0*np.pi/(2.0**m)\n    for i in range(n):\n        qc.p(phase_factor*S[i], i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AB01925FE41CC", "submission_order": 1, "result": "RE", "execution_time": "1402 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # Calculate the phase angle for the current qubit\n        phase_angle = 2 * np.pi * S[i] / (2 ** m)\n        \n        # Apply the phase gate to the i-th qubit\n        qc.p(phase_angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AB01925FE41CC", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n!pip install numpy\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # Calculate the phase angle for the current qubit\n        phase_angle = 2 * np.pi * S[i] / (2 ** m)\n        \n        # Apply the phase gate to the i-th qubit\n        qc.p(phase_angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AB01925FE41CC", "submission_order": 3, "result": "AC", "execution_time": "2695 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # Calculate the phase angle for the current qubit\n        phase_angle = 2 * np.pi * S[i] / (2 ** m)\n        \n        # Apply the phase gate to the i-th qubit\n        qc.p(phase_angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AB50A97D62FE6", "submission_order": 1, "result": "RE", "execution_time": "1224 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for x in range(2**n):\n        fx = sum(S[i] * ((x >> i) & 1) for i in range(n))\n        phase = 2 * np.pi * fx / (2**m)\n        qc.append(PhaseGate(phase), range(n))\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "ABF6840B751CF", "submission_order": 1, "result": "WA", "execution_time": "1897 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        theta=math.pi\n        #theta*=2**i\n        theta/=2**m\n        theta*=S[i]\n        \n        qc.p(theta,i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AC36B32B73A3D", "submission_order": 1, "result": "AC", "execution_time": "2028 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i]/2**m, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AC9153EF58202", "submission_order": 1, "result": "RE", "execution_time": "2937 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range (n):\n        theta=2*math.pi*S[i]/2**m\n        qc.p(theta,i)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AC9153EF58202", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range (n):\n        theta=2*math.pi*S[i]/2**m\n        qc.p(theta,i)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AD40A8C228B38", "submission_order": 1, "result": "RE", "execution_time": "1202 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        angle = 2 * pi * S[i] / (2 ** m)\n        qc.rz(angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AD40A8C228B38", "submission_order": 2, "result": "AC", "execution_time": "1811 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        angle = 2 * math.pi * S[i] / (2 ** m)\n        qc.rz(angle, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AD5FF868E6A44", "submission_order": 1, "result": "AC", "execution_time": "1908 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        angle = (2 * math.pi * S[i]) / (2 ** m)\n        qc.p(angle,i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AD712A9888AA9", "submission_order": 1, "result": "AC", "execution_time": "2333 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        lam = 2 * np.pi * S[i] / 2 ** m\n        qc.u(0, 0, lam, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "ADC0F575325BD", "submission_order": 1, "result": "WA", "execution_time": "2203 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(4*math.pi*S[i]/2**m,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "ADC0F575325BD", "submission_order": 2, "result": "WA", "execution_time": "1950 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(4*math.pi*S[i]/2**(m/n),i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "ADC0F575325BD", "submission_order": 3, "result": "AC", "execution_time": "2271 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i]/2**m,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AE988BAF16D5D", "submission_order": 1, "result": "RE", "execution_time": "1582 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2*math.pi*S[i]/2**m\n        qc.p(theta,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AE988BAF16D5D", "submission_order": 2, "result": "AC", "execution_time": "1786 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2*math.pi*S[i]/2**m\n        qc.p(theta,i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AECADED823952", "submission_order": 1, "result": "RE", "execution_time": "1442 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.q(2*math.pi*S[i] / 2**m)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AECADED823952", "submission_order": 2, "result": "RE", "execution_time": "1583 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i] / 2**m)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AECADED823952", "submission_order": 3, "result": "AC", "execution_time": "1801 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*S[i] / 2**m, i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF019F311E440", "submission_order": 1, "result": "RE", "execution_time": "1231 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply Hadamard gates to the first n qubits (to create superposition)\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply controlled-phase gates based on the values of S\n    for i in range(n):\n        for j in range(i, n):\n            if S[i] != 0:\n                angle = 2 * np.pi * S[i] / (2 ** m)\n                qc.cp(angle, j, n)  # Apply controlled-phase gate\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF019F311E440", "submission_order": 2, "result": "DLE", "execution_time": "1085 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n + m, m)\n    # Write your code here:\n    # Apply Hadamard gates to the first n qubits (to create superposition)\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply controlled-phase gates based on the values of S\n    for i in range(n):\n        for j in range(i, n):\n            if S[i] != 0:\n                angle = 2 * np.pi * S[i] / (2 ** m)\n                qc.cp(angle, j, n)  # Apply controlled-phase gate\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF019F311E440", "submission_order": 3, "result": "DLE", "execution_time": "1344 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n + m, m)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply the phase shift using controlled rotations\n    for i in range(n):\n        if S[i] != 0:\n            angle = 2 * np.pi * S[i] / (2 ** m)\n            # Apply multi-controlled phase shift\n            for control in range(n):\n                if control != i:\n                    qc.cp(angle, control, n)\n    \n    # Apply inverse Hadamard gates to the first n qubits to complete the QFT\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF019F311E440", "submission_order": 4, "result": "DLE", "execution_time": "1780 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n + m, m)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply the phase shift for the given S values\n    for i in range(n):\n        if S[i] != 0:\n            # Calculate the angle for the phase shift\n            angle = 2 * np.pi * S[i] / (2 ** m)\n            \n            # Apply the controlled-phase gate\n            for qubit in range(n):\n                if (i & (1 << qubit)) != 0:\n                    qc.cp(angle, qubit, n)  # Apply controlled-phase gate\n    \n    # Apply inverse QFT to undo the initial Hadamard gates\n    for qubit in range(n):\n        qc.h(qubit)\n        for k in range(qubit):\n            qc.cp(-np.pi / 2**(qubit - k), k, qubit)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF019F311E440", "submission_order": 5, "result": "DLE", "execution_time": "1196 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n + m, m)\n    # Write your code here:\n    # Apply Hadamard gates to the first n qubits (to create superposition)\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply controlled rotations to encode f(x) into the phase of the target qubits\n    for i in range(n):\n        if S[i] != 0:\n            # Calculate the phase angle for the S[i] value\n            angle = 2 * np.pi * S[i] / (2 ** m)\n            # Apply the controlled-phase gate to the target qubits\n            for j in range(m):\n                qc.crz(angle / (2 ** j), i, n + j)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF0AE7D306FE9", "submission_order": 1, "result": "RE", "execution_time": "1432 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = []\n    for item in S:\n        qc.p(2*pi/2**(m)*item)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF0AE7D306FE9", "submission_order": 2, "result": "AC", "execution_time": "2721 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    bits = []\n    for i, item in enumerate(S):\n        qc.p(2*pi/2**(m)*item, i)\n\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF0B5BD771F68", "submission_order": 1, "result": "RE", "execution_time": "1372 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2 * math.pi / (2 ** m) * S[i])\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF0B5BD771F68", "submission_order": 2, "result": "AC", "execution_time": "1904 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2 * math.pi / (2 ** m) * S[i], i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF13B925B8FEF", "submission_order": 1, "result": "RE", "execution_time": "1376 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)  # n qubits for the function and 1 auxiliary qubit\n    \n    # Apply a Hadamard gate to the last qubit\n    qc.h(n)\n    \n    # Apply controlled phase gates based on the function f(x)\n    for x in range(2 ** n):\n        f_x = sum(S[k] * ((x >> k) & 1) for k in range(n))\n        phase = np.exp(2j * np.pi * f_x / (2 ** m))\n        \n        # Apply the phase gate to the auxiliary qubit\n        if phase != 1:\n            qc.u1(np.angle(phase), n)  # U1 gate is used to apply the phase\n        \n    # Apply a Hadamard gate to the last qubit to complete the oracle\n    qc.h(n)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF13B925B8FEF", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister, ClassicalRegister\nfrom qiskit.circuit.library import PhaseGate\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    # Quantum and classical registers\n    q = QuantumRegister(n + 1, name='q')  # n qubits for function and 1 qubit for phase\n    c = ClassicalRegister(n, name='c')\n    qc = QuantumCircuit(q, c)\n    \n    # Apply Hadamard gates to all qubits (except the last one for phase)\n    qc.h(q[:n])\n    \n    # Apply controlled phase gates based on the function f(x)\n    for x in range(2 ** n):\n        f_x = sum(S[k] * ((x >> k) & 1) for k in range(n))\n        phase = np.exp(2j * np.pi * f_x / (2 ** m))\n        \n        # Apply controlled phase gate to the last qubit\n        if phase != 1:\n            qc.p(np.angle(phase), q[n])  # p gate applies phase to the last qubit\n    \n    # Optional: Apply additional operations if needed, such as using ancilla qubits\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF2073045BEC4", "submission_order": 1, "result": "WA", "execution_time": "1430 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(np.pi*S[i] / (2 ** m), i)\n    \n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF2073045BEC4", "submission_order": 2, "result": "RE", "execution_time": "1324 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    for i in range(n):\n        qc.x(i)\n        qc.p(np.pi * S[i] / (2 ** m), i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF2073045BEC4", "submission_order": 3, "result": "WA", "execution_time": "1270 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n        qc.p(np.pi * S[i] / (2 ** m), i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF2073045BEC4", "submission_order": 4, "result": "WA", "execution_time": "1599 ms", "memory": "181 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n        qc.p(2*np.pi * S[i] / (2 ** m), i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF2073045BEC4", "submission_order": 5, "result": "WA", "execution_time": "1133 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n        qc.p(2*np.pi * S[-i-1] / (2 ** m), i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF2073045BEC4", "submission_order": 6, "result": "WA", "execution_time": "1188 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n        qc.p(4*np.pi * S[i] / (2 ** m), i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC002_B5", "user": "AF2073045BEC4", "submission_order": 7, "result": "AC", "execution_time": "1831 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*np.pi * S[i] / (2 ** m), i)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A05FC3F208234", "submission_order": 1, "result": "WA", "execution_time": "1219 ms", "memory": "155 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef qfts(qc, i, n) -> QuantumCircuit:\n    for q in range(i):\n            qc.cp(-math.pi / 2 ** (i - q), q, i)\n    qc.h(i)\n \ndef iqft(qc,n):\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    for i in range(n):\n        qfts(qc,i,n)\n \n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n+m)\n \n    for j in range(m):\n        qc.h(j)\n \n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / 2**m) * 2**j\n            qc.cp(theta, i+m,j)\n \n    iqft(qc,m)\n \n    return qc\nsolve(5,2,(1,0,0,0,1))\n'''"}
{"problem": "QPC002_B6", "user": "A05FC3F208234", "submission_order": 2, "result": "WA", "execution_time": "1433 ms", "memory": "155 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef qfts(qc, i, n) -> QuantumCircuit:\n    for q in range(i):\n            qc.cp(-math.pi / 2 ** (i - q), q, i)\n    qc.h(i)\n \ndef iqft(qc,n):\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    for i in range(n):\n        qfts(qc,i,n)\n \n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n+m)\n \n    for j in range(m):\n        qc.h(j)\n \n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / 2**m) * 2**j\n            qc.cp(theta, i+m,j)\n \n    iqft(qc,m)\n \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A05FC3F208234", "submission_order": 3, "result": "WA", "execution_time": "1228 ms", "memory": "154 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef qfts(qc, i, n) -> QuantumCircuit:\n    for q in range(i):\n            qc.cp(-math.pi / 2 ** (i - q), q, i)\n    qc.h(i)\n \ndef iqft(qc,n):\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    for i in range(n):\n        qfts(qc,i,n)\n \n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n+m)\n \n    for j in range(m):\n        qc.h(j)\n \n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / 2**m) * 2**j\n            qc.cp(theta, j,i+m)\n \n    iqft(qc,m)\n \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A093844655B23", "submission_order": 1, "result": "RE", "execution_time": "1412 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**m, (i,j))\n    \n    for i in range(m // 2):\n        qc.swap(i, 2*n - i - 1) \n\n    for i in range(m - 1, -1, -1):\n        for j in range(i - 1, -1, -1):\n            qc.cp(-np.pi / 2**(i - j), n+i, n+j)\n        qc.h(n+i)\n        \n\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A093844655B23", "submission_order": 2, "result": "RE", "execution_time": "1593 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**m, i+n,j)\n    \n    for i in range(m // 2):\n        qc.swap(i, 2*n - i - 1) \n\n    for i in range(m - 1, -1, -1):\n        for j in range(i - 1, -1, -1):\n            qc.cp(-np.pi / 2**(i - j), n+i, n+j)\n        qc.h(n+i)\n                \n\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A093844655B23", "submission_order": 3, "result": "RE", "execution_time": "1129 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**m, i+n,j)\n    \n    for i in range(m // 2):\n        qc.swap(i+n, 2*n - i - 1) \n\n    for i in range(m - 1, -1, -1):\n        for j in range(i - 1, -1, -1):\n            qc.cp(-np.pi / 2**(i - j), n+i, n+j)\n        qc.h(n+i)\n                \n\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A093844655B23", "submission_order": 4, "result": "UGE", "execution_time": "1143 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**m, i+n,j)\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        # Write your code here:\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1) \n\n        for i in range(n):\n            for j in range(i):\n                qc.cp(-np.pi / 2**(i - j), j, i)\n            qc.h(i)\n        return qc\n    \n    qc.append(qft(m), range(n, n+m))\n            \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A093844655B23", "submission_order": 5, "result": "RE", "execution_time": "1449 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**m, i+n,j)\n\n    for i in range(n // 2):\n        qc.swap(i+n, n+n - i - 1) \n\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n            \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A093844655B23", "submission_order": 6, "result": "RE", "execution_time": "1342 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**m, i+n,j)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+n - i - 1) \n\n    for i in range(m):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n            \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A093844655B23", "submission_order": 7, "result": "RE", "execution_time": "1466 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**(n-i), i+n,j)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+n - i - 1) \n\n    for i in range(m):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n            \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A093844655B23", "submission_order": 8, "result": "AC", "execution_time": "1983 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**(m-i), i+n,j)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n\n    for i in range(m):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n            \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A0E3CCE2D2115", "submission_order": 1, "result": "WA", "execution_time": "1595 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # 各項 S[i] * x[i] を計算してyに加算\n    for i in range(n):\n        # S[i]の各ビットについて処理\n        for j in range(m):\n            bit_value = (S[i] >> j) & 1  # S[i]のj番目のビット\n            if bit_value == 1:\n                # x[i]が1のときのみy[j]をフリップ\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A123DBD2E3351", "submission_order": 1, "result": "WA", "execution_time": "1673 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(range(n, n+m))\n    for idx in range(0, n):\n        theta = 2 * math.pi * S[idx] / (2**m)\n        for jdx in range(n, n+m):\n            qc.cp(theta, idx, jdx)\n\n    qc = qc.compose(qft(m).inverse(), range(n, n+m))\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A123DBD2E3351", "submission_order": 2, "result": "WA", "execution_time": "1447 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(range(n, n+m))\n    for idx in range(0, n):\n        for jdx in range(n, n+m):\n            theta = 2 * math.pi * S[idx] * (jdx-n+1) / (2**m)\n            qc.cp(theta, idx, jdx)\n\n    qc = qc.compose(qft(m).inverse(), range(n, n+m))\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A123DBD2E3351", "submission_order": 3, "result": "WA", "execution_time": "1580 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(range(n, n+m))\n    for idx in range(0, n):\n        for jdx in range(n, n+m):\n            theta = 2 * math.pi * S[idx] * (jdx-n+1) / (2**m)\n            qc.cp(theta, idx, jdx)\n\n    qc = qc.compose(qft(m).inverse(), range(n, n+m))\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A123DBD2E3351", "submission_order": 4, "result": "WA", "execution_time": "1846 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (jdx+1) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A123DBD2E3351", "submission_order": 5, "result": "AC", "execution_time": "1858 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A20C0E4B41E35", "submission_order": 1, "result": "AC", "execution_time": "2442 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n# from qiskit.quantum_info import Statevector\n\ndef quantum_fourier_transform(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(i-1, -1, -1):\n            qc.cp(2*math.pi/(2**(i-j+1)), j, i)\n    \n    i = 0\n    while i<n-i-1:\n        qc.swap(i, n-i-1)\n        i += 1\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    # init = [0]*(2**(n+m))\n    # init[3] = 1\n    # qc.initialize(init)\n\n    # Write your code here:\n\n    qc.compose(quantum_fourier_transform(m), y, inplace=True)\n    for j in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(2**m)*(2**j), x[i], y[j])\n    qc.compose(quantum_fourier_transform(m).inverse(), y, inplace=True)\n\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2, 2, [1, 2])\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B6", "user": "A266591AA7DFC", "submission_order": 1, "result": "UGE", "execution_time": "1140 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    def qft(n):\n      qc = QuantumCircuit(n)\n      for i in range(n):\n        qc.h(-1-i)\n        for j in range(i+1,n):\n            qc.cp(2 * np.pi / 2**(j+1-i), -1-j, -1-i)\n      for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n      return qc\n\n    for i in range(n):\n      qc.p(2*np.pi*S[i]/2**m, x[i])\n    for j in range(m):\n      qc.h(y[j])\n\n    inv_qft = qft(m).inverse()\n    qc.append(inv_qft, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A3CC7611E64D4", "submission_order": 1, "result": "WA", "execution_time": "1423 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # Step through each qubit in x and apply the corresponding controlled addition\n    for i in range(n):\n        for j in range(m):\n            # Calculate the bit of S[i] that needs to be added to y[j] \n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])  # Apply a controlled-X operation based on x[i]\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A42D4991261E7", "submission_order": 1, "result": "WA", "execution_time": "1175 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        for j in range(m):\n            if ((S[i] >> j) & 1) == 1:\n                qc.cx(i, n + j)\n                if j < m - 1:\n                    qc.x(n + j)\n                    qc.cx(n + j, n + j + 1)\n                    qc.x(n + j)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A42D4991261E7", "submission_order": 2, "result": "WA", "execution_time": "1332 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        for j in range(m - 1, -1, -1):\n            if ((S[i] >> j) & 1) == 1:\n                qc.cx(i, n + j)\n                if j < m - 1:\n                    qc.x(n + j)\n                    qc.cx(n + j, n + j + 1)\n                    qc.x(n + j)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A42D4991261E7", "submission_order": 3, "result": "WA", "execution_time": "1645 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        for j in range(m):\n            if ((S[i] >> j) & 1) == 1:\n                qc.cx(i, n + j)\n                for k in range(j, m - 1):\n                    qc.x(n + k)\n                    qc.cx(n + k, n + k + 1)\n                    qc.x(n + k)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A42D4991261E7", "submission_order": 4, "result": "WA", "execution_time": "1433 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        for j in range(m):\n            if ((S[i] >> j) & 1) == 1:\n                qc.cx(i, n + j)\n                for k in range(j + 1, m):\n                    for s in range(j, k):\n                        qc.x(n + s)\n                    mcx = MCXGate(k - j)\n                    qc.append(mcx, range(n + j, n + k + 1))\n                    for s in range(j, k):\n                        qc.x(n + s)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A42D4991261E7", "submission_order": 5, "result": "AC", "execution_time": "1980 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        j = n - 1 - i\n        if i >= j:\n            break\n        qc.swap(i, j)\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            theta = 2 * pi / (2 ** (j + 1 - i))\n            qc.cp(theta, j, i)\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(n + j)\n        for i in range(n):\n            theta = 2 * pi * S[i] * 2 ** (j - m)\n            qc.cp(theta, j + n, i)\n\n    qc.compose(qft(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A4673A94888F5", "submission_order": 1, "result": "RE", "execution_time": "1118 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i)\n    for i in range(n):\n        for j in range(m):\n            qc.cp(2. * np.pi * S[i] * (2 ** i) * (2 **j) / (2 ** m), x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A4673A94888F5", "submission_order": 2, "result": "RE", "execution_time": "1140 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(i)\n    for i in range(n):\n        for j in range(m):\n            qc.cp(2. * np.pi * S[i] * (2 ** i) * (2 **j)/ (2 ** m), x[i], y[j])\n    def qft(n):\n        for itarg in range(n - 1, -1, -1):\n            qc.h(itarg)\n            for ictrl in range(itarg - 1, -1, -1):\n                power = ictrl - itarg - 1 + n\n                qc.cp((2 ** power) * 2. * np.pi / (2 ** n), ictrl, itarg)\n\n        for i in range(n // 2):\n            qc.swap(i, n - 1 - i)\n\n    qc.compose(qft(m).inverse(), y, inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A520A33F84E16", "submission_order": 1, "result": "WA", "execution_time": "1546 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:  \n                qc.cx(x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A5B6F098774A6", "submission_order": 1, "result": "UGE", "execution_time": "1071 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control:int, target:int, l:int):\n    #Apply Cphase operation\n    theta = 2 * math.pi / (1 << l)\n    qc.cp(theta, control, target)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Now swap qubits to reverse their order\n    for i in range(n//2):\n        qc.swap(i,n-i-1)\n\n    #Apply the qft\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1,n):\n            r(qc, j, i, j-i+1)\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    #Apply H-gate to all qubits in y\n    qc.h(y)\n\n    #Apply cphase gates\n    for k in range(m):\n        for i in range(n):\n            theta = 2 * math.pi * S[i]/ (1<<m)*(1<<k)\n            qc.cp(theta, y[k], x[i])\n\n    #Apply IQFT to y-reg\n    qc.append(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A5B6F098774A6", "submission_order": 2, "result": "RE", "execution_time": "1257 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control:int, target:int, l:int):\n    #Apply Cphase operation\n    theta = 2 * math.pi / (1 << l)\n    qc.cp(theta, control, target)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Now swap qubits to reverse their order\n    for i in range(n//2):\n        qc.cx(i,n-1)\n        qc.cx(n-i-1,i)\n        qc.cx(i,n-i-1)\n\n    #Apply the qft\n    for i in range(0,n):\n        qc.h(i)\n        for j in range(1,n-1):\n            r(qc, i+j, i, j+1)\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    #Apply H-gate to all qubits in y\n    qc.h(y)\n\n    #Apply cphase gates\n    for k in range(m):\n        for i in range(n):\n            theta = 2 * math.pi * S[i]/ (1<<m)*(1<<k)\n            qc.cp(theta, y[k], x[i])\n\n    #Apply IQFT to y-reg\n    qc.compose(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A5B6F098774A6", "submission_order": 3, "result": "RE", "execution_time": "1342 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control:int, target:int, l:int):\n    #Apply Cphase operation\n    theta = 2 * math.pi / (1 << l)\n    qc.cp(theta, control, target)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Now swap qubits to reverse their order\n    for i in range(n//2):\n        qc.cx(i,n-1)\n        qc.cx(n-i-1,i)\n        qc.cx(i,n-i-1)\n\n    #Apply the qft\n    for i in range(0,n):\n        qc.h(i)\n        for j in range(1,n-1):\n            r(qc, i+j, i, j+1)\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    #Apply H-gate to all qubits in y\n    qc.h(y)\n\n    #Apply cphase gates\n    for k in range(m):\n        for i in range(n):\n            theta = 2 * math.pi * S[i]/ (1<<m)*(1<<k)\n            qc.cp(theta, y[k], x[i])\n\n    #Apply IQFT to y-reg\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A5B6F098774A6", "submission_order": 4, "result": "RE", "execution_time": "1078 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control:int, target:int, l:int):\n    #Apply Cphase operation\n    theta = 2 * math.pi / (1 << l)\n    qc.cp(theta, control, target)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Now swap qubits to reverse their order\n    for i in range(n//2):\n        qc.cx(i,n-i-1)\n        qc.cx(n-i-1,i)\n        qc.cx(i,n-i-1)\n\n    #Apply the qft\n    for i in range(0,n):\n        qc.h(i)\n        for j in range(1,n-1):\n            r(qc, i+j, i, j+1)\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    #Apply H-gate to all qubits in y\n    qc.h(y)\n\n    #Apply cphase gates\n    for k in range(m):\n        for i in range(n):\n            theta = 2 * math.pi * S[i]/ (1<<m)*(1<<k)\n            qc.cp(theta, y[k], x[i])\n\n    #Apply IQFT to y-reg\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A5B6F098774A6", "submission_order": 5, "result": "AC", "execution_time": "1793 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control:int, target:int, l:int):\n    #Apply Cphase operation\n    theta = 2 * math.pi / (1 << l)\n    qc.cp(theta, control, target)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Now swap qubits to reverse their order\n    for i in range(n//2):\n        qc.cx(i,n-i-1)\n        qc.cx(n-i-1,i)\n        qc.cx(i,n-i-1)\n\n    #Apply the qft\n    for i in range(0,n):\n        qc.h(i)\n        for j in range(1,n-i):\n            r(qc, i+j, i, j+1)\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    #Apply H-gate to all qubits in y\n    qc.h(y)\n\n    #Apply cphase gates\n    for k in range(m):\n        for i in range(n):\n            theta = 2 * math.pi * S[i]/ (1<<m)*(1<<k)\n            qc.cp(theta, y[k], x[i])\n\n    #Apply IQFT to y-reg\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A61F70AC9F35C", "submission_order": 1, "result": "RE", "execution_time": "1356 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(min(n, m)):\n        angle = 2 * pi * S[i] / 2 ** m\n        qc.cp(angle, i, i + n)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A61F70AC9F35C", "submission_order": 2, "result": "WA", "execution_time": "1163 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(min(n, m)):\n        angle = 2 * pi * S[i] / 2 ** m\n        qc.cp(angle, i, i + n)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        bin_data = format(S[i], f'0{n}b')        \n        data_1_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '1' && idx < m]\n\n        if len(data_0_bits) > 0: \n            qc.cx(x[i], y[data_0_bits])\n        \n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 2, "result": "RE", "execution_time": "1106 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        bin_data = format(S[i], f'0{n}b')        \n        data_1_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0' and idx < m]\n\n        if len(data_0_bits) > 0: \n            qc.cx(x[i], y[data_0_bits])\n        \n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 3, "result": "WA", "execution_time": "1389 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        bin_data = format(S[i], f'0{n}b')        \n        data_1_bits = [idx for idx, digit in enumerate(reversed(bin_data)) if digit == '0' and idx < m]\n\n        if len(data_1_bits) > 0: \n            qc.cx(x[i], y[data_1_bits])\n        \n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 4, "result": "UGE", "execution_time": "1358 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        # Write your code here:\n        for i in range(n-1,-1,-1):\n            qc.h(i)\n            for j in range(i):\n                qc.cp(math.pi/(2**(j+1)), i-j-1, i)\n\n        for i in range(int(n/2)):\n            qc.swap(i,n-i-1)\n\n        return qc\n\n    qft_circ = qft(m)\n    qc.append(qft_circ, y)\n\n    for i in range(n):\n        for j in range(m):\n            phase = S[i] * 2**j / 2**m * math.pi\n            qc.cp(phase, x[i], y[j])\n\n    qc.append(qft_circ.inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 5, "result": "UGE", "execution_time": "1158 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i):\n            qc.cp(math.pi/(2**(j+1)), i-j-1, i)\n\n    for i in range(int(n/2)):\n        qc.swap(i,n-i-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qft_circ = qft(m)\n    qc.append(qft_circ, y)\n\n    for i in range(n):\n        for j in range(m):\n            phase = S[i] * 2**j / 2**m * math.pi\n            qc.cp(phase, x[i], y[j])\n\n    qc.append(qft_circ.inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 6, "result": "UGE", "execution_time": "1272 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        # Write your code here:\n        for i in range(n-1,-1,-1):\n            qc.h(i)\n            for j in range(i):\n                qc.cp(math.pi/(2**(j+1)), i-j-1, i)\n\n        for i in range(int(n/2)):\n            qc.cx(i,n-i-1)\n            qc.cx(n-i-1,i)\n            qc.cx(i,n-i-1)\n\n        return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qft_circ = qft(m)\n    qc.append(qft_circ, y)\n\n    for i in range(n):\n        for j in range(m):\n            phase = S[i] * 2**j / 2**m * math.pi\n            qc.cp(phase, x[i], y[j])\n\n    qc.append(qft_circ.inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 7, "result": "RE", "execution_time": "1164 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i):\n            qc.cp(math.pi/(2**(j+1)), i-j-1, i)\n\n    for i in range(int(n/2)):\n        qc.swap(i,n-i-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.append(qft_circ(m), y)\n\n    for i in range(n):\n        for j in range(m):\n            phase = S[i] * 2**j / 2**m * math.pi\n            qc.cp(phase, x[i], y[j])\n\n    qc.append(qft_circ(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 8, "result": "UGE", "execution_time": "1312 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i):\n            qc.cp(math.pi/(2**(j+1)), i-j-1, i)\n\n    for i in range(int(n/2)):\n        qc.swap(i,n-i-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.append(qft(m), y)\n\n    for i in range(n):\n        for j in range(m):\n            phase = S[i] * 2**j / 2**m * math.pi\n            qc.cp(phase, x[i], y[j])\n\n    qc.append(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 9, "result": "WA", "execution_time": "1288 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i):\n            qc.cp(math.pi/(2**(j+1)), i-j-1, i)\n\n    for i in range(int(n/2)):\n        qc.swap(i,n-i-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(qft(m), y)\n\n    for i in range(n):\n        for j in range(m):\n            phase = S[i] * 2**j / 2**m * math.pi\n            qc.cp(phase, x[i], y[j])\n\n    qc.compose(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6993D15856B8", "submission_order": 10, "result": "RE", "execution_time": "1203 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i):\n            qc.cp(math.pi/(2**(j+1)), i-j-1, i)\n\n    for i in range(int(n/2)):\n        qc.swap(i,n-i-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n\n    for i in range(n):\n        for j in range(m):\n            phase = S[i] * 2**j / 2**m * math.pi\n            qc.cp(phase, x[i], y[j])\n\n    qc.compos(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A6C66ABDC120A", "submission_order": 1, "result": "WA", "execution_time": "2165 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)  # Register for x\n    y = QuantumRegister(m)  # Register for f(x) mod 2^m\n    qc = QuantumCircuit(x, y)\n\n    # We will use a series of controlled additions to compute f(x)\n    for i in range(n):\n        if S[i] > 0:  # Only consider non-zero S[i]\n            # Convert S[i] to binary and apply controlled additions\n            binary_S = format(S[i], '0' + str(m) + 'b')  # Get binary representation of S[i]\n            for j in range(m):\n                if binary_S[m - 1 - j] == '1':  # Check if the j-th bit is set\n                    qc.cx(x[i], y[j])  # Apply CNOT from x[i] to y[j]\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A72CC47CA0CF1", "submission_order": 1, "result": "RE", "execution_time": "1157 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        for j in range(m):\n            x = (1 << j)\n            if (S[i] & x):\n                for k in range(1 << m):\n                    if(k % (2 * x) < x):\n                        qc.swap(k, k + x)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A72CC47CA0CF1", "submission_order": 2, "result": "RE", "execution_time": "1513 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nfrom qiskit.circuit.library import SwapGate\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        for j in range(m):\n            x = (1 << j)\n            if (S[i] & x):\n                for k in range(j, m - 1):\n                    if k == 0:\n                        qc.swap(0, 1)\n                    else:\n                        qc.append(SwapGate(0, k + 1).control(k - 1), range(1, k))\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A72CC47CA0CF1", "submission_order": 3, "result": "RE", "execution_time": "1298 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nfrom qiskit.circuit.library import SwapGate\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        for j in range(m):\n            x = (1 << j)\n            if (S[i] & x):\n                for k in range(j, m - 1):\n                    if k == 0:\n                        qc.swap(0, 1)\n                    else:\n                        qc.append(SwapGate(0, k + 1).control(k - 1), range(1, k))\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A72CC47CA0CF1", "submission_order": 4, "result": "RE", "execution_time": "1257 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nfrom qiskit.circuit.library import SwapGate\n\ndef solve(n: int, m: int, S) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        for j in range(m):\n            x = (1 << j)\n            if (S[i] & x):\n                for k in range(j, m - 1):\n                    if k == 0:\n                        qc.swap(0, 1)\n                    else:\n                        qc.append(SwapGate(0, k + 1).control(k - 1), range(1, k + 1))\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A72CC47CA0CF1", "submission_order": 5, "result": "RE", "execution_time": "1305 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nfrom qiskit.circuit.library import SwapGate\n\ndef solve(n: int, m: int, S) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        for j in range(m):\n            x = (1 << j)\n            if (S[i] & x):\n                for k in range(j, m - 1):\n                    if k == 0:\n                        qc.swap(0, 1)\n                    else:\n                        qc.append(SwapGate(0, k + 1).control(k), range(1, k + 1))\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A72CC47CA0CF1", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nfrom qiskit.circuit.library import SwapGate\n\ndef solve(n: int, m: int, S) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        for j in range(m):\n            x = (1 << j)\n            if (S[i] & x):\n                for k in range(min(j, m - 1):\n                    if k == 0:\n                        qc.swap(0, 1)\n                    else:\n                        qc.append(SwapGate(0, k + 1).control(k), range(1, k + 1))\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A72CC47CA0CF1", "submission_order": 7, "result": "RE", "execution_time": "1442 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nfrom qiskit.circuit.library import SwapGate\n\ndef solve(n: int, m: int, S) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        for j in range(m):\n            x = (1 << j)\n            if (S[i] & x):\n                for k in range(min(j, m - 1)):\n                    if k == 0:\n                        qc.swap(0, 1)\n                    else:\n                        qc.append(SwapGate(0, k + 1).control(k), range(1, k + 1))\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A770A77C704FD", "submission_order": 1, "result": "RE", "execution_time": "1921 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(n+j)\n    for i in range(n):\n        for j in range(m):\n            qc.cp(2*math.pi*S[i]/2**(m-j),i,n+j)\n    for j in range(m-1,-1,-1):\n        qc.h(n+j)\n        for l in range(j-1,-1,-1):\n            qc.cp(-2*math.pi/2**(j-l+1),n+l,n+j)\n    for k in range(m//2):\n        qc.swap(n+k,n+m-1-k)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A770A77C704FD", "submission_order": 2, "result": "AC", "execution_time": "2457 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(n+j)\n    for i in range(n):\n        for j in range(m):\n            qc.cp(2*math.pi*S[i]/2**(m-j),i,n+j)\n    for j in range(m-1,-1,-1):\n        qc.h(n+j)\n        for l in range(j-1,-1,-1):\n            qc.cp(-2*math.pi/2**(j-l+1),n+l,n+j)\n    for k in range(m//2):\n        qc.swap(n+k,n+m-1-k)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A7C0D4BBD3C06", "submission_order": 1, "result": "WA", "execution_time": "1139 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # Apply the oracle function f(x) = S0*x0 + S1*x1 + ... + Sn-1*xn-1\n    for i in range(n):\n        if S[i] != 0:\n            qc.cx(x[i], y[0])\n            for j in range(1, m):\n                if S[i] & (1 << (j - 1)):\n                    qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A7C0D4BBD3C06", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n     x = QuantumRegister(n, 'x')  # For the input bits\n    y = QuantumRegister(m, 'y')  # For the output bits\n    qc = QuantumCircuit(x, y)\n    \n    # We will use controlled addition to add S_i * x_i into the y register\n    \n    # Auxiliary qubit for carrying the addition results\n    carry = QuantumRegister(1, 'carry')\n    qc.add_register(carry)\n    \n    # Initialize carry qubit to |0⟩\n    qc.reset(carry[0])\n    \n    # Controlled addition circuits for each S_i\n    for i in range(n):\n        # We will be adding S_i * x_i to the y register\n        # Using controlled addition gates\n        s = S[i]\n        if s > 0:\n            # Use the controlled adder technique to add s*x_i to the y register\n            # Decompose s into its binary representation and add it conditionally\n            for bit in range(m):\n                if s & (1 << bit):\n                    qc.cx(x[i], y[bit])\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A7C0D4BBD3C06", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit: \n    x, y = QuantumRegister(n), QuantumRegister(m) \n    qc = QuantumCircuit(x, y) for i in range(n): \n    for j in range(m): \n        if (S[i] >> j) & 1: qc.cx(x[i], y[j]) \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A7C0D4BBD3C06", "submission_order": 4, "result": "AC", "execution_time": "1781 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A7CFCCAEDF382", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import *\n \n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # i を control として y に S[i] を加算しないといけない\n    for j in reversed(range(m)):\n        for i in range(n):\n            if S[i] & (1 << j):\n                # y に (1 << j) を加算\n                for k in range(n - 1, j, -1):\n                    qc.append(XGate().control(k - j + 1), [i] + list(range(n + j, n + k + 1)))\n                qc.cx(i, n + j)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A7CFCCAEDF382", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import XGate\n \n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # i を control として y に S[i] を加算しないといけない\n    for j in reversed(range(m)):\n        for i in range(n):\n            if S[i] & (1 << j):\n                # y に (1 << j) を加算\n                for k in range(n - 1, j, -1):\n                    qc.append(XGate().control(k - j + 1), [i] + list(range(n + j, n + k + 1)))\n                qc.cx(i, n + j)\n\n \n    return qc\n\n\nfrom qiskit.quantum_info import Statevector\nif __name__ == \"__main__\":\n    qc = solve(5, 5, [31, 31, 31, 31, 31])\n    qc.draw('mpl').savefig('a.png')\n    print(Statevector(qc))\n'''"}
{"problem": "QPC002_B6", "user": "A7CFCCAEDF382", "submission_order": 3, "result": "RE", "execution_time": "1312 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import XGate\n \n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # i を control として y に S[i] を加算しないといけない\n    for j in reversed(range(m)):\n        for i in range(n):\n            if S[i] & (1 << j):\n                # y に (1 << j) を加算\n                for k in range(n - 1, j, -1):\n                    qc.append(XGate().control(k - j + 1), [i] + list(range(n + j, n + k + 1)))\n                qc.cx(i, n + j)\n\n \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A7CFCCAEDF382", "submission_order": 4, "result": "UGE", "execution_time": "1229 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [j, i])\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # y をフーリエ変換\n    for i in range(m):\n        qc.h(n + i)\n    \n    # S[i] をフーリエ変換したものを掛ける\n    for i in range(n):\n        for j in range(m):\n            qc.append(U1Gate(2 * pi * S[i] / 2 ** (m - j)).control(1), [i, n + j])\n\n    # y を逆フーリエ変換\n    qc.append(QFT(m).inverse(), range(n, n + m))\n    \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A7CFCCAEDF382", "submission_order": 5, "result": "DLE", "execution_time": "1896 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [j, i])\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # y をフーリエ変換\n    for i in range(m):\n        qc.h(n + i)\n    \n    # S[i] をフーリエ変換したものを掛ける\n    for i in range(n):\n        for j in range(m):\n            qc.append(U1Gate(2 * pi * S[i] / 2 ** (m - j)).control(1), [i, n + j])\n\n    # y を逆フーリエ変換\n    qc.append(QFT(m).inverse(), range(n, n + m))\n    \n    return qc.decompose()\n'''"}
{"problem": "QPC002_B6", "user": "A7CFCCAEDF382", "submission_order": 6, "result": "AC", "execution_time": "1973 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [j, i])\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # y をフーリエ変換\n    for i in range(m):\n        qc.h(n + i)\n    \n    # S[i] をフーリエ変換したものを掛ける\n    for i in range(n):\n        for j in range(m):\n            qc.append(U1Gate(2 * pi * S[i] / 2 ** (m - j)).control(1), [i, n + j])\n\n    # y を逆フーリエ変換\n    for i in range(m//2):\n        qc.swap(n + i, n + m-i-1)\n    for i in range(m):\n        qc.h(n + i)\n        for j in range(i+1, m):\n            qc.append(U1Gate(-pi/2**(j-i)).control(1), [n + j, n + i])\n    \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A845C836C82DF", "submission_order": 1, "result": "WA", "execution_time": "1406 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n):\n        for j in range(m):\n            if (S[i] & (1 << j)) != 0:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A8CAF4302851D", "submission_order": 1, "result": "WA", "execution_time": "1142 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n, name='x')\n    y = QuantumRegister(m, name='y')\n    qc = QuantumCircuit(x, y)\n\n   \n    qc.reset(y)\n    for i in range(n):\n        if S[i] != 0:\n            for j in range(m):\n                if (S[i] >> j) & 1:\n                    qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A8CAF4302851D", "submission_order": 2, "result": "WA", "execution_time": "1367 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n, name='x')\n    y = QuantumRegister(m, name='y')\n    qc = QuantumCircuit(x, y)\n\n    # Apply controlled addition gates\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A92983DA3BC1B", "submission_order": 1, "result": "RE", "execution_time": "1429 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n \n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n \n    qc.h(y)\n \n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / 2**m) * 2**j\n            qc.cp(theta, x[i], y[j])\n \n    qc.compose(qft(m).inverse(), y, inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A92983DA3BC1B", "submission_order": 2, "result": "AC", "execution_time": "1725 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nimport math\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n \n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n \n    qc.h(y)\n \n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / 2**m) * 2**j\n            qc.cp(theta, x[i], y[j])\n \n    qc.compose(qft(m).inverse(), y, inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A93735C67CC40", "submission_order": 1, "result": "WA", "execution_time": "1140 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\nimport math\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n  qc = QuantumCircuit(n + m)\n  qc.x(0)\n  for i in range(m):\n    qc.h(n + i)\n  for i in range(n):\n    for j in range(m):\n      qc.append(PhaseGate(-2 * math.pi * S[i] / pow(2, m - j)).control(1), [i, n + j])\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  return qc\n'''"}
{"problem": "QPC002_B6", "user": "A93735C67CC40", "submission_order": 2, "result": "AC", "execution_time": "2064 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\nimport math\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n  qc = QuantumCircuit(n + m)\n  for i in range(m):\n    qc.h(n + i)\n  for i in range(n):\n    for j in range(m):\n      qc.append(PhaseGate(-2 * math.pi * S[i] / pow(2, m - j)).control(1), [i, n + j])\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 1, "result": "RE", "execution_time": "1370 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,m):\n        qc.h(i)\n    for i in range(n,m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(n,m):\n        if i < m-1-i:\n            qc.swap(i,m-1-i)\n\n    for i in range(n,m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), k, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 2, "result": "RE", "execution_time": "1584 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,m):\n        qc.h(i)\n    for i in range(n,m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 3, "result": "RE", "execution_time": "1255 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 4, "result": "RE", "execution_time": "1283 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,m):\n        qc.h(i)\n    for i in range(n,m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 5, "result": "RE", "execution_time": "1320 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,nm):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 6, "result": "RE", "execution_time": "1282 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    nms = n+m\n    for i in range(n,nms):\n        qc.h(i)\n    for i in range(n,m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,nm):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 7, "result": "WA", "execution_time": "1508 ms", "memory": "181 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    # for i in range(n,n+m):\n    #     for j in range(n):\n    #         qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    # for i in range(m):\n    #     if n+i < m-1-i:\n    #         qc.swap(n+i,m-1-i)\n\n    # for i in range(n,nm):\n    #     for j in range(n,i):\n    #         qc.cp(-np.pi/(2.0**(i-j)), j, i)\n    #     qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 8, "result": "RE", "execution_time": "1267 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    # for i in range(n,n+m):\n    #     for j in range(n):\n    #         qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 9, "result": "WA", "execution_time": "1457 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    # for i in range(n,n+m):\n    #     for j in range(n):\n    #         qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    # for i in range(n,n+m):\n    #     for j in range(n,i):\n    #         qc.cp(-np.pi/(2.0**(i-j)), j, i)\n    #     qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 10, "result": "WA", "execution_time": "1124 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.x(0)\n    #         qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    # for i in range(n,n+m):\n    #     for j in range(n,i):\n    #         qc.cp(-np.pi/(2.0**(i-j)), j, i)\n    #     qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 11, "result": "RE", "execution_time": "1488 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    # for i in range(n,n+m):\n    #     for j in range(n,i):\n    #         qc.cp(-np.pi/(2.0**(i-j)), j, i)\n    #     qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 12, "result": "RE", "execution_time": "1457 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(np.pi, 0, 1)\n            # qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    # for i in range(n,n+m):\n    #     for j in range(n,i):\n    #         qc.cp(-np.pi/(2.0**(i-j)), j, i)\n    #     qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 13, "result": "WA", "execution_time": "1081 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.x(0)\n            # qc.cp(np.pi, 0, 1)\n            # qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    # for i in range(n,n+m):\n    #     for j in range(n,i):\n    #         qc.cp(-np.pi/(2.0**(i-j)), j, i)\n    #     qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 14, "result": "WA", "execution_time": "1228 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    # for i in range(n,n+m):\n    #     for j in range(n,i):\n    #         qc.cp(-np.pi/(2.0**(i-j)), j, i)\n    #     qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 15, "result": "WA", "execution_time": "1362 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), j, i)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 16, "result": "WA", "execution_time": "1298 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**(i-n)), i, j)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 17, "result": "WA", "execution_time": "1875 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 18, "result": "RE", "execution_time": "1364 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/S[j]*(2.0**((n-1)-i)), i, j)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 19, "result": "WA", "execution_time": "1387 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n        \n    for i in range(m):\n        if n+i < m-1-i:\n            qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A99E5103D111F", "submission_order": 20, "result": "AC", "execution_time": "1778 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n        \n    # for i in range(m):\n    #     if n+i < m-1-i:\n    #         qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "A9D96D6719D4C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumRegister, QuantumCircuit\nfrom numpy import pi\n\ndef solve(n, m, s) -> QuantumCircuit:\n\tfrom qiskit.circuit.library import QFT\n\tx, y = QuantumRegister(n), QuantumRegister(m)\n\tqc = QuantumCircuit(x, y)\n\tfor i in range(n):\n\t\tqc.append(QFT(m).control(1), [x[i]] + list(y))\n\t\tfor j in range(m):\n\t\t\tqc.cp(2 * pi * s[i] / 2**(m - j), x[i], y[j])\n\t\tqc.append(QFT(m, inverse = True).control(1), [x[i]] + list(y))\n\treturn qc\n'''"}
{"problem": "QPC002_B6", "user": "A9D96D6719D4C", "submission_order": 2, "result": "DLE", "execution_time": "1780 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumRegister, QuantumCircuit\n\n# Adds 2 * len(qubits) circuit depth\ndef apply_QFT(qc, qubits, ctrl_qubit = None, inverse = False):\n\tfrom numpy import pi\n\tcoef = -pi if inverse else pi\n\tif ctrl_qubit:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.ch(ctrl_qubit, qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.mcp(coef / 2**(i - j), [ctrl_qubit, qubits[j]], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.cswap(ctrl_qubit, qubits[i], qubits[len(qubits) - 1 - i])\n\telse:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.h(qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.cp(coef / 2**(i - j), qubits[j], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.swap(qubits[i], qubits[len(qubits) - 1 - i])\n\treturn qc\n\ndef solve(n, m, s) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(m)\n\tqc = QuantumCircuit(x, y)\n\tfrom numpy import pi\n\tfor i in range(n):\n\t\tapply_QFT(qc, y, x[i])\n\t\tfor j in range(m):\n\t\t\tqc.cp(2 * pi * s[i] / 2**(m - j), x[i], y[j])\n\t\tapply_QFT(qc, y, x[i], inverse = True)\n\treturn qc\n'''"}
{"problem": "QPC002_B6", "user": "A9D96D6719D4C", "submission_order": 3, "result": "AC", "execution_time": "2597 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumRegister, QuantumCircuit\n\n# Adds 2 * len(qubits) circuit depth\ndef apply_QFT(qc, qubits, ctrl_qubit = None, inverse = False):\n\tfrom numpy import pi\n\tcoef = -pi if inverse else pi\n\tif ctrl_qubit:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.ch(ctrl_qubit, qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.mcp(coef / 2**(i - j), [ctrl_qubit, qubits[j]], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.cswap(ctrl_qubit, qubits[i], qubits[len(qubits) - 1 - i])\n\telse:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.h(qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.cp(coef / 2**(i - j), qubits[j], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.swap(qubits[i], qubits[len(qubits) - 1 - i])\n\treturn qc\n\ndef solve(n, m, s) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(m)\n\tqc = QuantumCircuit(x, y)\n\tfrom numpy import pi\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tapply_QFT(qc, y, inverse = True)\n\treturn qc\n'''"}
{"problem": "QPC002_B6", "user": "AA18282AD1861", "submission_order": 1, "result": "WA", "execution_time": "1233 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    # Implement the oracle\n    for i in range(n):\n        for j in range(m):\n            if (S[i] & (1 << j)) != 0:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AA18282AD1861", "submission_order": 2, "result": "WA", "execution_time": "1480 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    # Implement the oracle\n    for i in range(n):\n        si = S[i]\n        for j in range(m):\n            if si & 1:\n                qc.cx(x[i], y[j])\n            si >>= 1\n        \n        # Reverse the additions for qubits other than the least significant\n        if i > 0:\n            si = S[i]\n            for j in range(m-1, 0, -1):\n                if si & (1 << j):\n                    for k in range(j):\n                        qc.cx(y[j], y[k])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AA18282AD1861", "submission_order": 3, "result": "WA", "execution_time": "1499 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    # Implement the oracle\n    for i in range(n):\n        si = S[i]\n        for j in range(m):\n            if si & 1:\n                qc.cx(x[i], y[j])\n            si >>= 1\n        \n        # Reverse the additions for qubits other than the least significant\n        if i > 0:\n            si = S[i]\n            for j in range(m-1, 0, -1):\n                if si & (1 << j):\n                    for k in range(j):\n                        qc.cx(y[j], y[k])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AA18282AD1861", "submission_order": 4, "result": "WA", "execution_time": "1247 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # Implement f(x) using controlled rotations\n    for i in range(n):\n        for j in range(m):\n            angle = (S[i] * 2**j * 2 * pi) / (2**m)\n            qc.cry(angle, x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AA18282AD1861", "submission_order": 5, "result": "WA", "execution_time": "1770 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # Implement f(x) using controlled additions\n    for i in range(n):\n        # Convert S[i] to binary representation\n        si_binary = format(S[i], f'0{m}b')[::-1]  # Reverse for little-endian\n        \n        # Apply controlled-X gates for each bit of S[i]\n        for j in range(m):\n            if si_binary[j] == '1':\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AB55BEFC1BFD0", "submission_order": 1, "result": "AC", "execution_time": "1927 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AB907F5E55DD5", "submission_order": 1, "result": "WA", "execution_time": "1167 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef calc_f(m: int, S: list[int], qc: QuantumCircuit, r: QuantumRegister) -> None:\n    for i in range(len(r)):\n        qc.p(2 * math.pi / (2 ** m) * S[i], r[i])\n\n\ndef inv_qft(qc: QuantumCircuit, r: QuantumRegister) -> None:\n    n = len(r)\n\n    # swap\n    for i in range(n // 2):\n        qc.swap(i, r[n - 1 - i])\n\n    for i in reversed(range(n)):\n        for j in reversed(range(i + 1, n)):\n            theta = 2 * math.pi / (2 ** (j - i + 1))\n            qc.cp(- theta, r[n - 1 - j], r[n - 1 - i])\n        qc.h(r[n - 1 - i])\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    calc_f(m, S, qc, x)\n    inv_qft(qc, y)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AB907F5E55DD5", "submission_order": 2, "result": "RE", "execution_time": "1348 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(n - 1 - i)\n        for j in range(i + 1, n):\n            theta = 2 * math.pi / (2 ** (j - i + 1))\n            qc.cp(theta, n - 1 - j, n - 1 -i)\n\n    # swap\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    for j in range(m):\n        for i in range(n):\n            qc.cp(2 * math.pi / (2 ** m) * S[i] * (2 ** j), y[j], x[i])\n\n    qc.compose(qc_f, x, inplace=True)\n    qc.copmose(qft(m).inverse(), y, inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AB907F5E55DD5", "submission_order": 3, "result": "RE", "execution_time": "1217 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(n - 1 - i)\n        for j in range(i + 1, n):\n            theta = 2 * math.pi / (2 ** (j - i + 1))\n            qc.cp(theta, n - 1 - j, n - 1 -i)\n\n    # swap\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for j in range(m):\n        for i in range(n):\n            qc.cp(2 * math.pi / (2 ** m) * S[i] * (2 ** j), y[j], x[i])\n    qc.copmose(qft(m).inverse(), y, inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AB907F5E55DD5", "submission_order": 4, "result": "RE", "execution_time": "1291 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(n - 1 - i)\n        for j in range(i + 1, n):\n            theta = 2 * math.pi / (2 ** (j - i + 1))\n            qc.cp(theta, n - 1 - j, n - 1 -i)\n\n    # swap\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for j in range(m):\n        for i in range(n):\n            qc.cp(2 * math.pi / (2 ** m) * S[i] * (2 ** j), y[j], x[i])\n    qc.compose(qft(m).inverse(), y, inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AB907F5E55DD5", "submission_order": 5, "result": "RE", "execution_time": "1300 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for j in range(m):\n        for i in range(n):\n            qc.cp(2 * math.pi / (2 ** m) * S[i] * (2 ** j), y[j], x[i])\n    qc.compose(qft(m).inverse(), y, inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AB907F5E55DD5", "submission_order": 6, "result": "RE", "execution_time": "1422 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(n - 1 - i)\n        for j in range(i + 1, n):\n            theta = 2 * math.pi / (2 ** (j - i + 1))\n            qc.cp(theta, n - 1 - j, n - 1 - i)\n\n    # swap\n    for i in range(n // 2):\n        qc.swap(i, n - 1 - i)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n \n    qc.h(y)\n \n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / 2**m) * 2**j\n            qc.cp(theta, x[i], y[j])\n \n    qc.compose(qft(m).inverse(), y, inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "ABEC87D596E54", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # Apply X gates to flip the bits of y that correspond to non-zero coefficients in S\n    for i in range(n):\n        if S[i] != 0:\n            qc.x(y[S[i] % m])\n    \n    # Apply controlled-X gates to compute the sum modulo 2^m\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                (link unavailable)(x[i], y[j])\n    \n    # Apply X gates again to flip the bits of y back\n    for i in range(n):\n        if S[i] != 0:\n            qc.x(y[S[i] % m])\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AC0E38E100BD2", "submission_order": 1, "result": "WA", "execution_time": "1254 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(len(S)):\n        for j in range(m):\n            if (S[i]&(1<<j)) > 0:\n                for k in range(m-1, j, -1):\n                    qc.h(n+k)\n                    qc.mcp(math.pi, list(range(n,n+k)), n+k)\n                    qc.h(n+k)\n                qc.x(n+j)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AC0E38E100BD2", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(len(S)):\n        for j in range(m):\n            if (S[i]&(1<<j)) > 0:\n                for k in range(m-1, j-1, -1):\n                    qc.h(n+k)\n                    qc.mcp(math.pi, [i, **(list(range(n+j,n+k))) ], n+k)\n                    qc.h(n+k)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AC0E38E100BD2", "submission_order": 3, "result": "DLE", "execution_time": "1496 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(len(S)):\n        for j in range(m):\n            if (S[i]&(1<<j)) > 0:\n                for k in range(m-1, j-1, -1):\n                    qc.h(n+k)\n                    qc.mcp(math.pi, [i, *(list(range(n+j,n+k))) ], n+k)\n                    qc.h(n+k)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AC0E38E100BD2", "submission_order": 4, "result": "RE", "execution_time": "1684 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(len(S)):\n        for j in range(m-1, 0, -1):\n            rem = (1<<j)-S[i]%(1<<j)\n            for k in range(j-1, -1, -1):\n                if rem >= (1<<k):\n                    qc.mpc(math.pi, [ i, *(list(range(n+j-1, n+k-1, -1))) ], n+j)\n                    if k > 0:\n                        rem -= (1<<k)\n                        qc.x(n+k)\n            rem = (1<<j)-S[i]%(1<<j)\n            for k in range(j-1, -1, -1):\n                if rem >= (1<<k):\n                    if k > 0:\n                        rem -= (1<<k)\n                        qc.x(n+k)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AC0E38E100BD2", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(len(S)):\n        for j in range(m-1, 0, -1):\n            qc.h(n+j)\n            rem = (1<<j)-S[i]%(1<<j)\n            for k in range(j-1, -1, -1):\n                if rem <= (1<<k):\n                    qc.mpc(math.pi, [ i, *(list(range(n+j-1, n+k-1, -1))) ], n+j)\n                    if k > 0:\n                        qc.x(n+k)\n                else:\n                    rem -= (1<<k)\n            rem = (1<<j)-S[i]%(1<<j)\n            for k in range(j-1, -1, -1):\n                if rem > (1<<k):\n                    rem -= (1<<k)\n                else if k > 0:\n                    qc.x(n+k)\n            qc.h(n+j)\n            if (S[i]&(1<<j)) > 0:\n                qc.cx(i, n+j)\n        if S[i]%2 == 1:\n            qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AC0E38E100BD2", "submission_order": 6, "result": "DLE", "execution_time": "1540 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(len(S)):\n        for j in range(m-1, 0, -1):\n            qc.h(n+j)\n            rem = (1<<j)-S[i]%(1<<j)\n            for k in range(j-1, -1, -1):\n                if rem <= (1<<k):\n                    qc.mcp(math.pi, [ i, *(list(range(n+j-1, n+k-1, -1))) ], n+j)\n                    if k > 0:\n                        qc.x(n+k)\n                else:\n                    rem -= (1<<k)\n            rem = (1<<j)-S[i]%(1<<j)\n            for k in range(j-1, -1, -1):\n                if rem > (1<<k):\n                    rem -= (1<<k)\n                elif k > 0:\n                    qc.x(n+k)\n            qc.h(n+j)\n            if (S[i]&(1<<j)) > 0:\n                qc.cx(i, n+j)\n        if S[i]%2 == 1:\n            qc.cx(i, n)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AD58125C011A1", "submission_order": 1, "result": "AC", "execution_time": "1800 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "ADC1BE39EC707", "submission_order": 1, "result": "WA", "execution_time": "1466 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "ADC1BE39EC707", "submission_order": 2, "result": "WA", "execution_time": "1150 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(min(n, m)):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "ADC1BE39EC707", "submission_order": 3, "result": "WA", "execution_time": "1376 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    now = 0\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "ADC1BE39EC707", "submission_order": 4, "result": "WA", "execution_time": "1196 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    now = 0\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                for k in range(j + 1, m):\n                    if (S[i] >> k) & 1:\n                        qc.cx(y[k], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "ADC1BE39EC707", "submission_order": 5, "result": "WA", "execution_time": "1171 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit.circuit.library as qlib\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    now = 0\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                for k in range(j, m):\n                    qc.cx(x[i], y[k])\n\n    \n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF21F6BF33D48", "submission_order": 1, "result": "WA", "execution_time": "1246 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        for j in range(m):\n            if S[i] & (1<<m):\n                qc.cx(x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF612293F7B68", "submission_order": 1, "result": "WA", "execution_time": "1270 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    for i in range(2**n):\n        j = 0\n        for k in range(n):\n            j += ((i >> k) & 1) * S[k]\n        j %= 2**m\n\n        if i == j:\n            continue\n\n        for k in range(n):\n            if (i >> k) & 1 == 0:\n                qc.x(x[k])\n\n        for k in range(m):\n            if (j >> k) & 1 == 1:\n                qc.mcx(x, y[k])\n\n        for k in range(n):\n            if (i >> k) & 1 == 0:\n                qc.x(x[k])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF612293F7B68", "submission_order": 2, "result": "WA", "execution_time": "1140 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1 == 1:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF612293F7B68", "submission_order": 3, "result": "WA", "execution_time": "1890 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    for i in reversed(range(n)):\n        for j in range(m):\n            if (S[i] >> j) & 1 == 1:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 1, "result": "RE", "execution_time": "1726 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(n):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    qc.compose(qft(n), inplace=True, qubits=x)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(n).inverse(), inplace=True, qubits=x)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 2, "result": "WA", "execution_time": "1553 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    qc.compose(qft(n), inplace=True, qubits=x)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(n).inverse(), inplace=True, qubits=x)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 3, "result": "WA", "execution_time": "1404 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 4, "result": "WA", "execution_time": "1400 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 5, "result": "WA", "execution_time": "1472 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        # for i in range(n // 2):\n        #     qc.swap(i, n - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n            # qc.rz(math.pi * k / 2**i, y[i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n    # add_k_fourier(qc, 0, x)\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 6, "result": "WA", "execution_time": "1220 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n            # qc.rz(math.pi * k / 2**i, y[i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[n - i - 1])\n    # add_k_fourier(qc, 0, x)\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 7, "result": "WA", "execution_time": "1269 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n            # qc.rz(math.pi * k / 2**i, y[i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[n - i - 1], x[n - i - 1])\n    # add_k_fourier(qc, 0, x)\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 8, "result": "WA", "execution_time": "1802 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n            # qc.rz(math.pi * k / 2**i, y[i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[n - 1 - i], x[i])\n    # add_k_fourier(qc, 0, x)\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 9, "result": "WA", "execution_time": "1186 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n            # qc.rz(math.pi * k / 2**i, y[i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n    # add_k_fourier(qc, 0, x)\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 10, "result": "WA", "execution_time": "1632 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[m - i - 1])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 11, "result": "WA", "execution_time": "1287 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[m - i - 1])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[n - i - 1], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 12, "result": "WA", "execution_time": "1171 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[m - i - 1])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[n - i - 1], x[n - i - 1])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 13, "result": "WA", "execution_time": "1423 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        # for i in range(n // 2):\n        #     qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[m - 1 - i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 14, "result": "WA", "execution_time": "1245 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 15, "result": "WA", "execution_time": "1351 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 16, "result": "WA", "execution_time": "1465 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 17, "result": "WA", "execution_time": "1338 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 18, "result": "WA", "execution_time": "1689 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 19, "result": "WA", "execution_time": "1177 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(n: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, n):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(n // 2):\n            qc.swap(i, n - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(2 * math.pi * k / 2**i, control, y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 20, "result": "WA", "execution_time": "1421 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control, y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 21, "result": "WA", "execution_time": "1644 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[m - 1 - i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 22, "result": "WA", "execution_time": "1321 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[m - 1 - i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 23, "result": "WA", "execution_time": "1241 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 24, "result": "WA", "execution_time": "1602 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        # for i in range(num_qubits // 2):\n        #     qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[m - 1 - i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 25, "result": "WA", "execution_time": "1312 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        # for i in range(num_qubits // 2):\n        #     qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[m - 1 - i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[n - 1 - i], x[n - 1 - i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 26, "result": "WA", "execution_time": "1216 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        # for i in range(num_qubits // 2):\n        #     qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[m - 1 - i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 27, "result": "WA", "execution_time": "1352 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        # for i in range(num_qubits // 2):\n        #     qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[m - 1 - i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 28, "result": "WA", "execution_time": "1278 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(\n                math.pi * k / 2 ** (m - 1 - i),\n                control_qubit=control,\n                target_qubit=y[m - 1 - i],\n            )\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 29, "result": "WA", "execution_time": "1272 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    S = S[::-1]\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / (2**i), control_qubit=control, target_qubit=y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 30, "result": "RE", "execution_time": "1225 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / (2**i), control_qubit=control, target_qubit=y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    qc.measure_all()\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 31, "result": "WA", "execution_time": "1477 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(len(y)):\n            qc.crz(math.pi * k / (2**i), control_qubit=control, target_qubit=y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 32, "result": "WA", "execution_time": "1478 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(len(y)):\n            qc.crz(\n                math.pi * k / (2**i), control_qubit=control, target_qubit=y[m - 1 - i]\n            )\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 33, "result": "UGE", "execution_time": "1400 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(len(y)):\n            qc.crz(\n                math.pi * k / (2**i), control_qubit=control, target_qubit=y[m - 1 - i]\n            )\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    # qc.compose(qft(m), inplace=True, qubits=y)\n    qc.append(qft(m).to_gate().inverse(), qargs=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    # qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n    qc.append(qft(m).to_gate().inverse(), qargs=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 34, "result": "WA", "execution_time": "1526 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(len(y)):\n            qc.crz(\n                math.pi * k / (2**i), control_qubit=control, target_qubit=y[m - 1 - i]\n            )\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    qc = qc.compose(qft(m), qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc = qc.compose(qft(m).inverse(), qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 35, "result": "WA", "execution_time": "1263 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        c: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(len(y)):\n            c.crz(\n                math.pi * k / (2**i), control_qubit=control, target_qubit=y[m - 1 - i]\n            )\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 36, "result": "WA", "execution_time": "1139 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        c: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(len(y)):\n            c.crz(math.pi * k / (2**i), control_qubit=control, target_qubit=y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    swap_qubits(qc, x)\n    swap_qubits(qc, y)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    swap_qubits(qc, x)\n    swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 37, "result": "WA", "execution_time": "1431 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k(c: QuantumCircuit, k: int, control: QuantumRegister) -> QuantumCircuit:\n        for i in range(len(y)):\n            c.crz(math.pi * k / (2**i), control_qubit=control, target_qubit=y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 38, "result": "WA", "execution_time": "1523 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k(c: QuantumCircuit, k: int, control: QuantumRegister) -> QuantumCircuit:\n        for i in range(len(y)):\n            c.crz(math.pi * k / (2**i), control_qubit=control, target_qubit=y[i])\n\n    # qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(m):\n        qc.h(y[i])\n\n    for i in range(n):\n        add_k(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 39, "result": "WA", "execution_time": "1532 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k(c: QuantumCircuit, k: int, control: QuantumRegister) -> QuantumCircuit:\n        for i in range(len(y)):\n            c.crz(math.pi * k / (2**i), control_qubit=control, target_qubit=y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, x)\n    swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AF66D93D9F2B1", "submission_order": 40, "result": "WA", "execution_time": "1340 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, i, j)\n                rotation /= 2\n        for i in range(num_qubits // 2):\n            qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k(c: QuantumCircuit, k: int, control: QuantumRegister) -> QuantumCircuit:\n        for i in range(len(y)):\n            c.crz(math.pi * k / (2**i), control_qubit=control, target_qubit=y[i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n    # swap_qubits(qc, y)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, x)\n    swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFCFBFE162BCC", "submission_order": 1, "result": "UGE", "execution_time": "1481 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef IQFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(-math.pi/2**j, n-i-j-1, n-i-1)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n\n    return qc\n\n\ndef U(n: int, m: int, pow: int, S: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*S[i]*pow/2**m, i)\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m):\n        qc.h(y[i])\n        qc.append(U(n, m, 2**i, S).to_gate().control(1), [y[i]]+[x[i] for i in range(n)])\n    qc.append(IQFT(m).to_gate(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFCFBFE162BCC", "submission_order": 2, "result": "UGE", "execution_time": "1063 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # IQFT\n    qc0 = QuantumCircuit(m)\n    for i in range(m):\n        qc0.h(m-i-1)\n        for j in range(1, m-i):\n            qc0.cp(-math.pi/2**j, m-i-j-1, m-i-1)\n    for i in range(m//2):\n        qc0.swap(i, m-i-1)\n    IQFT = qc0.to_gate()\n\n    for j in range(m):\n        qc.h(y[j])\n        # Oracle B5\n        qc1 = QuantumCircuit(n)\n        for i in range(n):\n            qc1.p(2*math.pi*S[i]*2**i/2**m, i)\n        U = qc1.to_gate()\n        \n        qc.append(U.control(1), [y[j]]+[x[i] for i in range(n)])\n\n    qc.append(IQFT, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFCFBFE162BCC", "submission_order": 3, "result": "WA", "execution_time": "1432 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(y[j])\n        # Oracle B5\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]*2**i/2**m, y[j], x[i])\n        \n    #IQFT\n    for i in range(m):\n        qc.h(y[m-i-1])\n        for j in range(1, m-i):\n            qc.cp(-math.pi/2**j, y[m-i-j-1], y[m-i-1])\n    for i in range(m//2):\n        qc.swap(i, y[m-i-1])\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFCFBFE162BCC", "submission_order": 4, "result": "WA", "execution_time": "2040 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(y[j])\n        # Oracle B5\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]*2**i/2**m, y[j], x[i])\n        \n    #IQFT\n    qc.compose(QFT(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFCFBFE162BCC", "submission_order": 5, "result": "WA", "execution_time": "1103 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(y[j])\n        # Oracle B5\n        for i in range(n):\n            qc.cp((2*math.pi*S[i]/2**m)*2**i, y[j], x[i])\n        \n    #IQFT\n    qc.compose(QFT(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFCFBFE162BCC", "submission_order": 6, "result": "WA", "execution_time": "1407 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(y[j])\n        # Oracle B5\n        for i in range(n):\n            qc.cp((2*math.pi*S[i]/2**m)*2**i, y[j], x[i])\n        \n    #IQFT\n    qc.compose(qft(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFCFBFE162BCC", "submission_order": 7, "result": "AC", "execution_time": "2419 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(y[j])\n        # Oracle B5\n        for i in range(n):\n            qc.cp((2*math.pi*S[i]/2**m)*2**j, y[j], x[i])\n        \n    #IQFT\n    qc.compose(qft(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFFDBD2D5BB36", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    QFT(qc, list(range(n, n + m)))\n\n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / (2 ** m)) * 2 ** j\n            qc.cp(theta, x[i], y[])\n\n    QFT(qc, list(range(n, n + m)), inversed = True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFFDBD2D5BB36", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    QFT(qc, list(range(n, n + m)))\n\n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / (2 ** m)) * 2 ** j\n            qc.cp(theta, x[i], y[])\n\n    QFT(qc, list(range(n, n + m)), inversed = True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFFDBD2D5BB36", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    QFT(qc, list(range(n, n + m)))\n\n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / (2 ** m)) * 2 ** j\n            qc.cp(theta, x[i], y[])\n\n    QFT(qc, list(range(n, n + m)), inversed = True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFFDBD2D5BB36", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    QFT(qc, list(range(n, n + m)))\n\n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / (2 ** m)) * 2 ** j\n            qc.cp(theta, x[i], y[])\n\n    QFT(qc, list(range(n, n + m)), inversed = True)\n\n    return qc\n'''"}
{"problem": "QPC002_B6", "user": "AFFDBD2D5BB36", "submission_order": 5, "result": "AC", "execution_time": "1969 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    QFT(qc, list(range(n, n + m)))\n\n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / (2 ** m)) * 2 ** j\n            qc.cp(theta, x[i], y[j])\n\n    QFT(qc, list(range(n, n + m)), inversed = True)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A010B2AB25235", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister, AncillaRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    # Define quantum registers\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(m, 'y')\n    anc = AncillaRegister(n, 'anc')\n    qc = QuantumCircuit(x, y, anc)\n    \n    # Compute f(x) using controlled addition\n    # We need to add `S_i` to `y` for each `x_i` == 1\n    \n    # To compute f(x) = S_0*x_0 + S_1*x_1 + ... + S_{n-1}*x_{n-1}\n    # We will use ancilla qubits to temporarily store intermediate sums\n    \n    for i in range(n):\n        if S[i] > 0:\n            # Convert S[i] to binary representation\n            binary_S_i = [int(b) for b in format(S[i], f'0{m}b')]\n            for j in range(m):\n                if binary_S_i[j] == 1:\n                    # Apply controlled additions to the `y` qubits\n                    qc.cx(x[i], y[j])\n                    \n    # Use ancilla qubits to facilitate the controlled additions\n    for i in range(n):\n        if S[i] > 0:\n            # Apply controlled adders to add S_i to the y register\n            binary_S_i = [int(b) for b in format(S[i], f'0{m}b')]\n            for j in range(m):\n                if binary_S_i[j] == 1:\n                    qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A010B2AB25235", "submission_order": 2, "result": "RE", "execution_time": "1198 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    # Create quantum registers for x and y\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(m, 'y')\n    \n    # Create the quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # Function to add value to a register with controlled addition\n    def controlled_addition(x_reg, y_reg, value):\n        bin_value = format(value, f'0{len(y_reg)}b')\n        for bit, q in zip(bin_value, y_reg):\n            if bit == '1':\n                qc.cx(x_reg[0], q)\n                x_reg = x_reg[1:]\n\n    # Add S_i to y for each x_i == 1\n    for i in range(n):\n        if S[i] > 0:\n            controlled_addition([x[i]], y, S[i])\n    \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A010B2AB25235", "submission_order": 3, "result": "WA", "execution_time": "1299 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    # Create quantum registers for x and y\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(m, 'y')\n    \n    # Create the quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # Implement the controlled additions\n    for i in range(n):\n        # Create a controlled adder for each bit\n        bin_S_i = format(S[i], f'0{m}b')  # Get binary representation of S[i]\n        \n        # Apply controlled additions based on the binary representation of S[i]\n        for j in range(m):\n            if bin_S_i[j] == '1':\n                # Apply a controlled-X gate if the bit is 1\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A010B2AB25235", "submission_order": 4, "result": "WA", "execution_time": "1417 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    # Create quantum registers for x and y\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(m, 'y')\n    \n    # Create the quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # Iterate over each bit of x and the corresponding S coefficient\n    for i in range(n):\n        # Get the binary representation of S[i]\n        bin_S_i = format(S[i], f'0{m}b')\n        \n        # For each bit in the binary representation, apply a controlled addition\n        for j in range(m):\n            if bin_S_i[j] == '1':\n                # Apply controlled-X gate to add the corresponding bit of S[i]\n                qc.cx(x[i], y[j])\n                \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A15434FC0502B", "submission_order": 1, "result": "RE", "execution_time": "1033 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef qft(n:int)->QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for k in range(n):\n        j = n-1-k\n        if k>=j:\n            break\n        qc.swap(k,j)\n    for i in range(n):\n        qc.h(i)\n        for l in range(i+1,n):\n            theta = 2 * pi / (2**(j+1-i))\n            qc.cp(theta, j , i)\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(m), y, inplace=True)\n    for j in range(m):\n        for i in range(n):\n            theta = 2 * pi * S[i] * 2 ** (j - m)\n            qc.cp(theta, j + n, i)\n\n    qc.compose(qft(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A15434FC0502B", "submission_order": 2, "result": "AC", "execution_time": "1695 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef qft(n:int)->QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for k in range(n):\n        j = n-1-k\n        if k>=j:\n            break\n        qc.swap(k,j)\n    for i in range(n):\n        qc.h(i)\n        for l in range(i+1,n):\n            theta = 2 * pi / (2**(l+1-i))\n            qc.cp(theta, l, i)\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(m), y, inplace=True)\n    for j in range(m):\n        for i in range(n):\n            theta = 2 * pi * S[i] * 2 ** (j - m)\n            qc.cp(theta, j + n, i)\n\n    qc.compose(qft(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A23E81762211B", "submission_order": 1, "result": "AC", "execution_time": "2922 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [j, i])\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # y をフーリエ変換\n    for i in range(m//2):\n        qc.swap(n + i, n + m-i-1)\n    for i in range(m):\n        qc.h(n + i)\n        for j in range(i+1, m):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [n + j, n + i])\n    \n    # S[i] をフーリエ変換したものを掛ける\n    for i in range(n):\n        for j in range(m):\n            qc.append(U1Gate(2 * pi * S[i] / 2 ** (m - j)).control(1), [i, n + j])\n\n    # y を逆フーリエ変換\n    for i in range(m//2):\n        qc.swap(n + i, n + m-i-1)\n    for i in range(m):\n        qc.h(n + i)\n        for j in range(i+1, m):\n            qc.append(U1Gate(-pi/2**(j-i)).control(1), [n + j, n + i])\n    \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A28B387CC71A6", "submission_order": 1, "result": "WA", "execution_time": "1159 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for qubit in x:\n        qc.h(qubit)\n    \n    # Apply the controlled-U gates based on the function f(x)\n    for i in range(n):\n        for j in range(m):\n            if S[i] != 0:\n                angle = 2 * np.pi * S[i] / (2 ** m)\n                # Apply controlled-phase (CRZ) gate to the target qubits\n                qc.crz(angle / (2 ** j), x[i], y[j])\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A28B387CC71A6", "submission_order": 2, "result": "WA", "execution_time": "1118 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Loop over each qubit in the x register\n    for i in range(n):\n        # For each qubit in x, add controlled-phase gates to the y qubits\n        for j in range(m):\n            # Calculate the angle for the controlled-phase gate\n            angle = 2 * np.pi * S[i] / (2 ** m)\n            # Apply controlled-phase gates\n            qc.crz(angle, x[i], y[j])\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A28B387CC71A6", "submission_order": 3, "result": "WA", "execution_time": "1507 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        # Add S[i] to y if x[i] is 1\n        if S[i] != 0:\n            for j in range(m):\n                if (S[i] >> j) & 1:\n                    qc.cx(x[i], y[j])\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A3876D9F91990", "submission_order": 1, "result": "WA", "execution_time": "1949 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m-1,-1,-1):\n        qc.h(n+j)\n        for l in range(j-1,-1,-1):\n            qc.cp(2*math.pi/2**(j-l+1),n+l,n+j)\n    for i in range(n):\n        for j in range(m):\n            qc.cp(2*math.pi*S[i]/2**(m-j),i,n+j)\n    for j in range(m-1,-1,-1):\n        qc.h(n+j)\n        for l in range(j-1,-1,-1):\n            qc.cp(-2*math.pi/2**(j-l+1),n+l,n+j)\n    for k in range(m//2):\n        qc.swap(n+k,n+m-1-k)\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A3876D9F91990", "submission_order": 2, "result": "AC", "execution_time": "2550 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m-1,-1,-1):\n        qc.h(n+j)\n        for l in range(j-1,-1,-1):\n            qc.cp(2*math.pi/2**(j-l+1),n+l,n+j)\n    for k in range(m//2):\n        qc.swap(n+k,n+m-1-k)\n    for i in range(n):\n        for j in range(m):\n            qc.cp(2*math.pi*S[i]/2**(m-j),i,n+j)\n    for j in range(m-1,-1,-1):\n        qc.h(n+j)\n        for l in range(j-1,-1,-1):\n            qc.cp(-2*math.pi/2**(j-l+1),n+l,n+j)\n    for k in range(m//2):\n        qc.swap(n+k,n+m-1-k)\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A39DC6DB64991", "submission_order": 1, "result": "UGE", "execution_time": "1700 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n# from qiskit.quantum_info import Statevector\n\ndef quantum_fourier_transform(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(i-1, -1, -1):\n            qc.cp(2*math.pi/(2**(i-j+1)), j, i)\n    \n    i = 0\n    while i<n-i-1:\n        qc.swap(i, n-i-1)\n        i += 1\n    \n    return qc.to_gate()\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    # init = [0]*(2**(n+m))\n    # init[3] = 1\n    # qc.initialize(init)\n\n    # Write your code here:\n\n    qc.append(quantum_fourier_transform(m), y)\n    for j in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(2**m)*(2**j), x[i], y[j])\n    qc.append(quantum_fourier_transform(m).inverse(), y)\n\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2, 2, [1, 2])\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B7", "user": "A39DC6DB64991", "submission_order": 2, "result": "AC", "execution_time": "2553 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n# from qiskit.quantum_info import Statevector\n\ndef quantum_fourier_transform(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(i-1, -1, -1):\n            qc.cp(2*math.pi/(2**(i-j+1)), j, i)\n    \n    i = 0\n    while i<n-i-1:\n        qc.swap(i, n-i-1)\n        i += 1\n    \n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    # init = [0]*(2**(n+m))\n    # init[3] = 1\n    # qc.initialize(init)\n\n    # Write your code here:\n\n    qc.compose(quantum_fourier_transform(m), y, inplace=True)\n    for j in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(2**m)*(2**j), x[i], y[j])\n    qc.compose(quantum_fourier_transform(m).inverse(), y, inplace=True)\n\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2, 2, [1, 2])\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_B7", "user": "A4347C9150F3A", "submission_order": 1, "result": "AC", "execution_time": "1841 ms", "memory": "156 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\n \ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    qft_m = qft(m)\n \n    qc.compose(qft_m, y, inplace=True)\n \n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / 2**m) * 2**j\n            qc.cp(theta, x[i], y[j])\n \n    qc.compose(qft_m.inverse(), y, inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A66704218582A", "submission_order": 1, "result": "AC", "execution_time": "2498 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumRegister, QuantumCircuit\n\n# Let n = len(qubits)\n# if no ctrl_qubits, adds 2 * len(qubits) circuit depth\n# otherwise,\n#  if n % 2 == 0, adds n * (n/2 + 1) circuit depth\n#  otherwise, adds (n-1) * ((n-1)/2 + 1) + n circuit depth\ndef apply_QFT(qc, qubits, ctrl_qubit = None, inverse = False):\n\tfrom numpy import pi\n\tcoef = -pi if inverse else pi\n\tif ctrl_qubit:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.ch(ctrl_qubit, qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.mcp(coef / 2**(i - j), [ctrl_qubit, qubits[j]], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.cswap(ctrl_qubit, qubits[i], qubits[len(qubits) - 1 - i])\n\telse:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.h(qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.cp(coef / 2**(i - j), qubits[j], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.swap(qubits[i], qubits[len(qubits) - 1 - i])\n\treturn qc\n\ndef solve(n, m, s) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(m)\n\tqc = QuantumCircuit(x, y)\n\tfrom numpy import pi\n\tapply_QFT(qc, y)\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tapply_QFT(qc, y, inverse = True)\n\treturn qc\n'''"}
{"problem": "QPC002_B7", "user": "A8EF837D31151", "submission_order": 1, "result": "WA", "execution_time": "1489 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    for i in range(m - 1, -1, -1):\n        qc.h(i+n)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i+n, j+n)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n        \n    \n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**(m-i), i+n,j)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n\n    for i in range(m):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n            \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A8EF837D31151", "submission_order": 2, "result": "WA", "execution_time": "1655 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m - 1, -1, -1):\n        qc.h(i+n)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i+n, j+n)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n        \n    \n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**(m-i), i+n,j)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n\n    for i in range(m):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n            \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A8EF837D31151", "submission_order": 3, "result": "AC", "execution_time": "2585 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(m - 1, -1, -1):\n        qc.h(i+n)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i+n, j+n)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n        \n    \n    for i in range(m):\n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**(m-i), i+n,j)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n\n    for i in range(m):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n            \n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A8FEEDB0837DA", "submission_order": 1, "result": "AC", "execution_time": "2164 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qft_m = qft(m)\n    qc = qc.compose(qft_m, y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft_m.inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A97CA1BABDC98", "submission_order": 1, "result": "WA", "execution_time": "1216 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        # for i in range(num_qubits // 2):\n        #     qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[m - 1 - i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[n - 1 - i], x[n - 1 - i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A97CA1BABDC98", "submission_order": 2, "result": "WA", "execution_time": "1432 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    import math\n\n    def qft(num_qubits: int) -> QuantumCircuit:\n        qc = QuantumCircuit(num_qubits)\n        for i in range(num_qubits):\n            qc.h(i)\n            rotation = math.pi / 2\n            for j in range(i + 1, num_qubits):\n                qc.cp(rotation, j, i)\n                rotation /= 2\n        # for i in range(num_qubits // 2):\n        #     qc.swap(i, num_qubits - i - 1)\n        # qc = qc.reverse_bits()\n        return qc\n\n    def add_k_fourier(\n        qc: QuantumCircuit, k: int, control: QuantumRegister\n    ) -> QuantumCircuit:\n        for i in range(m):\n            qc.crz(math.pi * k / 2**i, control_qubit=control, target_qubit=y[m - 1 - i])\n\n    def swap_qubits(qc: QuantumCircuit, x: QuantumRegister):\n        for i in range(len(x) // 2):\n            qc.swap(x[i], x[len(x) - i - 1])\n\n    # swap_qubits(qc, x)\n\n    qc.compose(qft(m), inplace=True, qubits=y)\n\n    for i in range(n):\n        add_k_fourier(qc, S[i], x[i])\n\n    qc.compose(qft(m).inverse(), inplace=True, qubits=y)\n\n    # swap_qubits(qc, y)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "A9935C912EE02", "submission_order": 1, "result": "AC", "execution_time": "1856 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc = qc.compose(qft(m), y)\n\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AA245B0BCEF7B", "submission_order": 1, "result": "RE", "execution_time": "1239 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # Apply controlled addition for each term in the function f(x)\n    for i in range(n):\n        # We use a controlled adder with x[i] controlling the addition of S[i]\n        # Use the basic Toffoli and CNOT gates to achieve this\n        if S[i] != 0:\n            qc.append(qc.cx(x[i], y[0]), [x[i], y[0]])\n            for j in range(1, m):\n                qc.append(qc.cx(x[i], y[j]), [x[i], y[j]])\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AA245B0BCEF7B", "submission_order": 2, "result": "WA", "execution_time": "1274 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n, name='x')\n    y = QuantumRegister(m, name='y')\n    qc = QuantumCircuit(x, y)\n    \n    # Apply controlled addition for each coefficient S[i]\n    for i in range(n):\n        coeff = S[i]\n        # Use multi-controlled addition gates to add the coefficients\n        for j in range(m):\n            if (coeff >> j) & 1:\n                # Apply a controlled-X gate for each bit in y if the corresponding bit in coeff is 1\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AA245B0BCEF7B", "submission_order": 3, "result": "AC", "execution_time": "2031 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qft_m = qft(m)\n    qc = qc.compose(qft_m, y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft_m.inverse(), y)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AAAEE23E97666", "submission_order": 1, "result": "WA", "execution_time": "2019 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # We will use a temporary register to hold the carry bits for addition\n    carry = QuantumRegister(m)\n    qc.add_register(carry)\n    \n    # Initialize carry bits to 0\n    for j in range(m):\n        qc.x(carry[j])  # Set carry bits to 0 initially\n    \n    # Iterate over each bit of x\n    for i in range(n):\n        if S[i] > 0:  # Only if S[i] is non-zero\n            # We need to add S[i] to y if x[i] is 1\n            # Convert S[i] to binary and apply controlled additions\n            s_bin = format(S[i], f'0{m}b')  # Get binary representation of S[i]\n            for j in range(m):\n                if s_bin[j] == '1':\n                    # Apply controlled addition of 1 to y[j] if x[i] is 1\n                    qc.cx(x[i], y[j])  # Controlled NOT gate\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AC9D71ECA10BF", "submission_order": 1, "result": "RE", "execution_time": "1296 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        j = n - 1 - i\n        if i >= j:\n            break\n        qc.swap(i, j)\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            theta = 2 * pi / (2 ** (j + 1 - i))\n            qc.cp(theta, j, i)\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(m), y, inplace=True)\n    for j in range(m):\n        for i in range(n):\n            theta = 2 * pi * S[i] * 2 ** (j - m)\n            qc.cp(theta, j + n, i)\n\n    qc.compose(qft(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AC9D71ECA10BF", "submission_order": 2, "result": "AC", "execution_time": "2371 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        j = n - 1 - i\n        if i >= j:\n            break\n        qc.swap(i, j)\n\n    for i in range(n):\n        qc.h(i)\n        for j in range(i + 1, n):\n            theta = 2 * pi / (2 ** (j + 1 - i))\n            qc.cp(theta, j, i)\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(m), y, inplace=True)\n    for j in range(m):\n        for i in range(n):\n            theta = 2 * pi * S[i] * 2 ** (j - m)\n            qc.cp(theta, j + n, i)\n\n    qc.compose(qft(m).inverse(), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AD00E29DFCCE5", "submission_order": 1, "result": "AC", "execution_time": "2021 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\ndef IQFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(-math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # QFT\n    qc.compose(QFT(m), y, inplace=True)\n\n    for j in range(m):\n        # Oracle B5\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]*2**j/2**m, y[j], x[i])\n        \n    # IQFT\n    qc.compose(IQFT(m), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AD62A7C2BA8D0", "submission_order": 1, "result": "AC", "execution_time": "2050 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\nimport math\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n  x, y = QuantumRegister(n), QuantumRegister(m)\n  qc = QuantumCircuit(x, y)\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(-2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  for i in range(n):\n    for j in range(m):\n      qc.append(PhaseGate(-2 * math.pi * S[i] / pow(2, m - j)).control(1), [i, n + j])\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  return qc\n'''"}
{"problem": "QPC002_B7", "user": "AD9F702F4B699", "submission_order": 1, "result": "WA", "execution_time": "1705 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        # Loop through each bit of y\n        for j in range(m):\n            # If the j-th bit of S[i] is 1, apply a controlled-NOT gate\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AD9F702F4B699", "submission_order": 2, "result": "WA", "execution_time": "1535 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AD9F702F4B699", "submission_order": 3, "result": "RE", "execution_time": "1473 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    def add_value_to_register(value, target_register):\n        \"\"\"Adds 'value' to the target quantum register (in-place addition).\"\"\"\n        num_bits = len(target_register)\n        for i in range(num_bits):\n            if (value >> i) & 1:  # if the ith bit of value is 1\n                qc.cx(target_register[i], target_register[(i + 1) % num_bits])  # Controlled-X\n\n    # Iterate over all possible states of the n qubits\n    for i in range(2 ** n):\n        x_bits = [int(bit) for bit in format(i, f'0{n}b')]\n        f_x = sum(S[j] * x_bits[j] for j in range(n))\n        \n        # Add f_x to the y register\n        add_value_to_register(f_x, y)\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AE6005B9AD206", "submission_order": 1, "result": "WA", "execution_time": "1235 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    # Implement controlled additions\n    for i in range(n):\n        for j in range(m):\n            # Determine if we need to add 2^j to y[j] based on S[i] and controlled by x[i]\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AEBDBE560A29E", "submission_order": 1, "result": "AC", "execution_time": "2121 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    QFT(qc, list(range(n, n + m)))\n\n    for j in range(m):\n        for i in range(n):\n            theta = (2 * math.pi * S[i] / (2 ** m)) * 2 ** j\n            qc.cp(theta, x[i], y[j])\n\n    QFT(qc, list(range(n, n + m)), inversed = True)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AF797AEB95CAF", "submission_order": 1, "result": "RE", "execution_time": "1114 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n        \n    # for i in range(m):\n    #     if n+i < m-1-i:\n    #         qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AF797AEB95CAF", "submission_order": 2, "result": "WA", "execution_time": "1624 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n        \n    # for i in range(m):\n    #     if n+i < m-1-i:\n    #         qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AF797AEB95CAF", "submission_order": 3, "result": "RE", "execution_time": "1248 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as n\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in reversed(range(n,n+m)):\n        qc.h(i)\n        for j in reversed(range(n,i)):\n            qc.cp(np.pi/(2.0 ** (i-j)), j, i)\n\n    for i in range(n):\n        if i < n-1-i:\n            qc.swap(i,n-1-i)\n    \n    # for i in range(n,n+m):\n    #     qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n        \n    # for i in range(m):\n    #     if n+i < m-1-i:\n    #         qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AF797AEB95CAF", "submission_order": 4, "result": "WA", "execution_time": "1141 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in reversed(range(n,n+m)):\n        qc.h(i)\n        for j in reversed(range(n,i)):\n            qc.cp(np.pi/(2.0 ** (i-j)), j, i)\n\n    for i in range(n):\n        if i < n-1-i:\n            qc.swap(i,n-1-i)\n    \n    # for i in range(n,n+m):\n    #     qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n        \n    # for i in range(m):\n    #     if n+i < m-1-i:\n    #         qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AF797AEB95CAF", "submission_order": 5, "result": "AC", "execution_time": "2335 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in reversed(range(n,n+m)):\n        qc.h(i)\n        for j in reversed(range(n,i)):\n            qc.cp(np.pi/(2.0 ** (i-j)), j, i)\n\n    # for i in range(n,n+m):\n    #     for j in range(n,i):\n    #         qc.cp()\n    #     qc.h(i)\n\n    \n\n\n    # for i in range(n,n+m):\n    #     qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n        \n    # for i in range(m):\n    #     if n+i < m-1-i:\n    #         qc.swap(n+i,m-1-i)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B7", "user": "AF9BADE98B09C", "submission_order": 1, "result": "AC", "execution_time": "1856 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\ndef IQFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(-math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\n\ndef solve(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # QFT\n    qc.compose(QFT(m), y, inplace=True)\n\n    for j in range(m):\n        # Oracle B5\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]*2**j/2**m, y[j], x[i])\n        \n    # IQFT\n    qc.compose(IQFT(m), y, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A038FB304628C", "submission_order": 1, "result": "WA", "execution_time": "1456 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n\n    ### B6\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n    ### B2\n\n    for i in range(n, n+m):\n        if L&(1<<i) == 0:\n            qc.x(i)\n    if m == 1:\n        qc.p(theta, n+m-1)\n    elif m == 2:\n        qc.cp(theta, n+m-2, n+m-1)\n    else:\n        qc.mcp(theta, list(range(n, n+m-1)), n+m-1)\n    for i in range(n, n+m):\n        if L&(1<<i) == 0:\n            qc.x(i)\n\n    ### B6(uncomputation)\n    for i in reversed(range(n,n+m)):\n        qc.h(i)\n        for j in reversed(range(n,i)):\n            qc.cp(np.pi/(2.0**(i-j)), j, i)\n\n    for i in reversed(range(n,n+m)):\n        for j in reversed(range(n)):\n            qc.cp(-2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n    \n    for i in range(n,n+m):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A038FB304628C", "submission_order": 2, "result": "AC", "execution_time": "1813 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n\n    ### B6\n\n    for i in range(n,n+m):\n        qc.h(i)\n    for i in range(n,n+m):\n        for j in range(n):\n            qc.cp(2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n\n    for i in range(n,n+m):\n        for j in range(n,i):\n            qc.cp(-np.pi/(2.0**(i-j)), j, i)\n        qc.h(i)\n\n    ### B2\n\n    for i in range(n, n+m):\n        if L&(1<<(i-n)) == 0:\n            qc.x(i)\n    if m == 1:\n        qc.p(theta, n+m-1)\n    elif m == 2:\n        qc.cp(theta, n+m-2, n+m-1)\n    else:\n        qc.mcp(theta, list(range(n, n+m-1)), n+m-1)\n    for i in range(n, n+m):\n        if L&(1<<(i-n)) == 0:\n            qc.x(i)\n\n    ### B6(uncomputation)\n    for i in reversed(range(n,n+m)):\n        qc.h(i)\n        for j in reversed(range(n,i)):\n            qc.cp(np.pi/(2.0**(i-j)), j, i)\n\n    for i in reversed(range(n,n+m)):\n        for j in reversed(range(n)):\n            qc.cp(-2.0*np.pi/(2.0**m)*S[j]*(2.0**((n+m-1)-i)), i, j)\n    \n    for i in range(n,n+m):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A23AC0B958363", "submission_order": 1, "result": "RE", "execution_time": "1117 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**(m-i), i+n,j)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n\n    for i in range(m):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n\n\n\n\n\n    for i in range(m):\n        if not ((L>>i)&1):\n            qc.x(i+n)\n    if m==1:\n        qc.p(theta,n)\n        \n    else :\n        qc.mcp(theta,[i+n for i in range(m-1)],n+m-1)\n    \n\n    for i in range(m):\n        if not ((L>>i)&1):\n            qc.x(i+n)\n\n\n\n\n\n    for i in range(m - 1, -1, -1):\n        qc.h(i+n)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i+n, j+n)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n\n    for i in range(m):\n        for j in range(n):\n            qc.cp(-2*np.pi*S[j]/2**(m-i), i+n,j)\n        \n        qc.h(i+n)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A23AC0B958363", "submission_order": 2, "result": "AC", "execution_time": "1977 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(m):\n        qc.h(i+n)\n    \n        for j in range(n):\n            qc.cp(2*np.pi*S[j]/2**(m-i), i+n,j)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n\n    for i in range(m):\n        for j in range(i):\n            qc.cp(-np.pi / 2**(i - j), j+n, i+n)\n        qc.h(i+n)\n\n\n\n\n\n    for i in range(m):\n        if not ((L>>i)&1):\n            qc.x(i+n)\n    if m==1:\n        qc.p(theta,n)\n        \n    else :\n        qc.mcp(theta,[i+n for i in range(m-1)],n+m-1)\n    \n\n    for i in range(m):\n        if not ((L>>i)&1):\n            qc.x(i+n)\n\n\n\n\n\n    for i in range(m - 1, -1, -1):\n        qc.h(i+n)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / 2**(i - j), i+n, j+n)\n\n    for i in range(m // 2):\n        qc.swap(i+n, n+m - i - 1) \n\n    for i in range(m):\n        for j in range(n):\n            qc.cp(-2*np.pi*S[j]/2**(m-i), i+n,j)\n        \n        qc.h(i+n)\n    \n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A2546BF54C488", "submission_order": 1, "result": "RE", "execution_time": "1433 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    for i in range(n):\n        for j in range(n):\n            if S[j] != 0:\n                qc.cx(x[j], y[i])\n                qc.rz(2 * np.pi * S[j] / (2 ** m), y[i])\n                qc.cx(x[j], y[i])\n    \n    \n    for i in range(2 ** n):\n        \n        f_x = sum(S[j] * ((i >> j) & 1) for j in range(n))\n        if f_x % (2 ** m) == L:\n            qc.rz(theta, y[0])\n    \n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A2BE8DD9836E2", "submission_order": 1, "result": "AC", "execution_time": "1789 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\ndef add(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc = qc.compose(qft(m), y)\n\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    qc.compose(add(n, m, S), inplace=True)\n\n    lbits = []\n    for idx in range(0, m):\n        lbits.append(bool(L % 2))\n        L = L // 2\n\n    for idx in range(0, m):\n        if not lbits[idx]:\n            qc.x(y[idx])\n\n    if m == 1:\n        qc.p(theta, y[0])\n    else:\n        qc.mcp(theta, y[0:m-1], y[m-1])\n\n    for idx in range(0, m):\n        if not lbits[idx]:\n            qc.x(y[idx])\n\n    qc.compose(add(n, m, S).inverse(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A3BE1EACE0185", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n        for i in range(n):\n        for _ in range(S[i]):  # Add S_i to the ancilla qubits based on x_i\n            qc.cx(i, n + (S[i] % m))\n\n    # Step 2: Check if f(x) mod 2^m equals L mod 2^m\n    # Convert L to binary and store in ancilla qubits for comparison\n    L_bin = format(L % (2**m), f'0{m}b')\n    for i in range(m):\n        if L_bin[i] == '0':\n            qc.x(n + i)\n\n    # Apply controlled phase shift if the ancilla qubits match L mod 2^m\n    qc.mcx(list(range(n, n + m)), 0)  # Multi-controlled X gate\n    qc.p(theta, 0)  # Apply phase shift e^(iθ) to the first qubit\n    qc.mcx(list(range(n, n + m)), 0)  # Undo the multi-controlled X gate\n\n    # Reapply X gates to reset ancilla qubits to the original state\n    for i in range(m):\n        if L_bin[i] == '0':\n            qc.x(n + i)\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A45C0C8820FBF", "submission_order": 1, "result": "RE", "execution_time": "1779 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    QFT(qc, list(range(n, n+m)))\n\n    for j in range(m):\n        for i in range(n):\n            theta = 2 * math.pi * S[i] * (2 ** j) / (2 ** m)\n            qc.cp(theta, x[i], y[j])\n\n\n    QFT(qc, list(range(n, n+m)), inversed = True)\n\n    for i in range(m):\n        if not (1 << i) & L:\n            qc.x(y[i])\n \n    if n == 1:\n        qc.p(theta, n + m - 1)\n    else:\n        qc.mcp(theta, list(n + range(m - 1)), n + m - 1)\n \n    for i in range(m):\n        if not (1 << i) & L:\n            qc.x(y[i])\n\n    QFT(qc, list(range(n, n+m)))\n\n    for j in range(m):\n        for i in range(n):\n            theta = -2 * math.pi * S[i] * (2 ** j) / (2 ** m)\n            qc.cp(theta, x[i], y[j])\n\n\n    QFT(qc, list(range(n, n+m)), inversed = True)\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A571499297E74", "submission_order": 1, "result": "AC", "execution_time": "2879 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o_f(n,m,S), inplace=True)\n    qc.compose(o_Pshift(m,L,theta),qubits=list(range(n,n+m)),inplace=True)\n    qc.compose(o_f(n,m,S).inverse(), inplace=True)\n\n    return qc\n\ndef o_f(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m-1,-1,-1):\n        qc.h(n+j)\n        for l in range(j-1,-1,-1):\n            qc.cp(2*math.pi/2**(j-l+1),n+l,n+j)\n    for k in range(m//2):\n        qc.swap(n+k,n+m-1-k)\n    for i in range(n):\n        for j in range(m):\n            qc.cp(2*math.pi*S[i]/2**(m-j),i,n+j)\n    for j in range(m-1,-1,-1):\n        qc.h(n+j)\n        for l in range(j-1,-1,-1):\n            qc.cp(-2*math.pi/2**(j-l+1),n+l,n+j)\n    for k in range(m//2):\n        qc.swap(n+k,n+m-1-k)\n    return qc\n    \ndef o_Pshift(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    L_code = format(L, f'0{n}b')[::-1]\n    print(L_code)\n    for i in range(n):\n        if L_code[i] == \"0\":\n            qc.x(i)\n    if n >= 2:\n        qc.mcp(theta,list(range(n-1)),n-1)\n    else:\n        qc.p(theta, 0)\n    for i in range(n):\n        if L_code[i] == \"0\":\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A62F577BBFF2E", "submission_order": 1, "result": "WA", "execution_time": "1339 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\nimport math\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n  x, y = QuantumRegister(n), QuantumRegister(m)\n  qc = QuantumCircuit(x, y)\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(-2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  for i in range(n):\n    for j in range(m):\n      qc.append(PhaseGate(-2 * math.pi * S[i] / pow(2, m - j)).control(1), [i, n + j])\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  for i in range(m):\n    if ((L >> i) & 1) == 0:\n      qc.x(n + i)\n  if m == 1:\n    qc.p(theta, n)\n  else:\n    qc.append(PhaseGate(theta).control(m - 1), list(range(n, n + m)))\n  for i in range(m):\n    if ((L >> i) & 1) == 0:\n      qc.x(n + i)\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  for i in range(n):\n    for j in range(m):\n      qc.append(PhaseGate(2 * math.pi * S[i] / pow(2, m - j)).control(1), [i, n + j])\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(-2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)  \n  return qc\n'''"}
{"problem": "QPC002_B8", "user": "A62F577BBFF2E", "submission_order": 2, "result": "AC", "execution_time": "2784 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates  import PhaseGate\nimport math\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n  x, y = QuantumRegister(n), QuantumRegister(m)\n  qc = QuantumCircuit(x, y)\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(-2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  for i in range(n):\n    for j in range(m):\n      qc.append(PhaseGate(-2 * math.pi * S[i] / pow(2, m - j)).control(1), [i, n + j])\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  for i in range(m):\n    if ((L >> i) & 1) == 0:\n      qc.x(n + i)\n  if m == 1:\n    qc.p(theta, n)\n  else:\n    qc.append(PhaseGate(theta).control(m - 1), list(range(n, n + m)))\n  for i in range(m):\n    if ((L >> i) & 1) == 0:\n      qc.x(n + i)\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(-2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)\n  for i in range(n):\n    for j in range(m):\n      qc.append(PhaseGate(2 * math.pi * S[i] / pow(2, m - j)).control(1), [i, n + j])\n  for i in range(m - 1, -1, -1):\n    for j in range(m - 1, i, -1):\n      qc.append(PhaseGate(2 * math.pi * math.pow(2, i - 1 - j)).control(1), [n + i, n + j])\n    qc.h(n + i)\n  for i in range(m // 2):\n    qc.cx(n + i, n + m - 1 - i)\n    qc.cx(n + m - 1 - i, n + i)\n    qc.cx(n + i, n + m - 1 - i)  \n  return qc\n'''"}
{"problem": "QPC002_B8", "user": "A6484B66CD984", "submission_order": 1, "result": "RE", "execution_time": "1077 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [j, i])\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # y をフーリエ変換\n    for i in range(m):\n        qc.h(n + i)\n    \n    # S[i] をフーリエ変換したものを掛ける\n    for i in range(n):\n        for j in range(m):\n            qc.append(U1Gate(2 * pi * S[i] / 2 ** (m - j)).control(1), [i, n + j])\n\n    # y を逆フーリエ変換\n    for i in range(m//2):\n        qc.swap(n + i, n + m-i-1)\n    for i in range(m):\n        qc.h(n + i)\n        for j in range(i+1, m):\n            qc.append(U1Gate(-pi/2**(j-i)).control(1), [n + j, n + i])\n    \n    # y == L のところに e^iθ を掛ける\n    for i in range(m):\n        if ~L & (1 << i):\n            qc.x(n + i)\n    qc.append(U1Gate(theta).control(m-1) if m else U1Gate(theta), range(n, n+m))\n    for i in range(m):\n        if ~L & (1 << i):\n            qc.x(n + i)\n\n    # さっきの逆\n    \n    # y をフーリエ変換\n    for i in range(m//2):\n        qc.swap(n + i, n + m-i-1)\n    for i in range(m):\n        qc.h(n + i)\n        for j in range(i+1, m):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [n + j, n + i])\n    \n    # S[i] をフーリエ変換したものを割る\n    for i in range(n):\n        for j in range(m):\n            qc.append(U1Gate(-2 * pi * S[i] / 2 ** (m - j)).control(1), [i, n + j])\n    \n    # y をフーリエ変換\n    for i in range(m):\n        qc.h(n + i)\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A6484B66CD984", "submission_order": 2, "result": "AC", "execution_time": "1782 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import U1Gate\nfrom math import pi\n \ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [j, i])\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # y をフーリエ変換\n    for i in range(m):\n        qc.h(n + i)\n    \n    # S[i] をフーリエ変換したものを掛ける\n    for i in range(n):\n        for j in range(m):\n            qc.append(U1Gate(2 * pi * S[i] / 2 ** (m - j)).control(1), [i, n + j])\n\n    # y を逆フーリエ変換\n    for i in range(m//2):\n        qc.swap(n + i, n + m-i-1)\n    for i in range(m):\n        qc.h(n + i)\n        for j in range(i+1, m):\n            qc.append(U1Gate(-pi/2**(j-i)).control(1), [n + j, n + i])\n    \n    # y == L のところに e^iθ を掛ける\n    for i in range(m):\n        if ~L & (1 << i):\n            qc.x(n + i)\n    qc.append(U1Gate(theta).control(m-1) if m > 1 else U1Gate(theta), range(n, n+m))\n    for i in range(m):\n        if ~L & (1 << i):\n            qc.x(n + i)\n\n    # さっきの逆\n    \n    # y をフーリエ変換\n    for i in range(m//2):\n        qc.swap(n + i, n + m-i-1)\n    for i in range(m):\n        qc.h(n + i)\n        for j in range(i+1, m):\n            qc.append(U1Gate(pi/2**(j-i)).control(1), [n + j, n + i])\n    \n    # S[i] をフーリエ変換したものを割る\n    for i in range(n):\n        for j in range(m):\n            qc.append(U1Gate(-2 * pi * S[i] / 2 ** (m - j)).control(1), [i, n + j])\n    \n    # y をフーリエ変換\n    for i in range(m):\n        qc.h(n + i)\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A717787B16F78", "submission_order": 1, "result": "WA", "execution_time": "1238 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # Compute the value of L mod 2^m\n    L_mod = L % (2 ** m)\n    \n    # Apply the function f(x) = S0*x0 + S1*x1 + ... + S(n-1)*x(n-1)\n    for i in range(n):\n        if S[i] != 0:\n            qc.cx(x[i], y[0])  # Add a controlled-NOT (CNOT) to y based on x[i]\n            for j in range(1, m):\n                if S[i] & (1 << j):\n                    qc.cx(x[i], y[j])\n    \n    # Apply the phase shift conditional on f(x) == L mod 2^m\n    for i in range(m):\n        if (L_mod & (1 << i)) != 0:\n            qc.h(y[i])\n    \n    # Apply the phase shift\n    qc.rz(theta, y[0])\n    \n    # Revert the state to its original form\n    for i in range(m):\n        if (L_mod & (1 << i)) != 0:\n            qc.h(y[i])\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A717787B16F78", "submission_order": 2, "result": "AC", "execution_time": "1948 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(m, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A8433E17B2CF5", "submission_order": 1, "result": "RE", "execution_time": "1824 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumRegister, QuantumCircuit\n\n# Let n = len(qubits)\n# if no ctrl_qubits, adds 2 * len(qubits) circuit depth\n# otherwise,\n#  if n % 2 == 0, adds n * (n/2 + 1) circuit depth\n#  otherwise, adds (n-1) * ((n-1)/2 + 1) + n circuit depth\ndef apply_QFT(qc, qubits, ctrl_qubit = None, inverse = False):\n\tfrom numpy import pi\n\tcoef = -pi if inverse else pi\n\tif ctrl_qubit:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.ch(ctrl_qubit, qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.mcp(coef / 2**(i - j), [ctrl_qubit, qubits[j]], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.cswap(ctrl_qubit, qubits[i], qubits[len(qubits) - 1 - i])\n\telse:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.h(qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.cp(coef / 2**(i - j), qubits[j], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.swap(qubits[i], qubits[len(qubits) - 1 - i])\n\treturn qc\n\ndef solve(n, m, L, s, theta) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(m)\n\tqc = QuantumCircuit(x, y)\n\tfrom numpy import pi\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tapply_QFT(qc, y, inverse = True)\n\tif m == 1:\n\t\tif L == 0:\n\t\t\tqc.x(y[0])\n\t\tqc.p(theta)\n\t\tif L == 0:\n\t\t\tqc.x(y[0])\n\telse:\n\t\tfor j in range(m):\n\t\t\tif ~L >> j & 1:\n\t\t\t\tqc.x(y[j])\n\t\tqc.mcp(theta, range(m - 1), m - 1)\n\t\tfor j in range(m):\n\t\t\tif ~L >> j & 1:\n\t\t\t\tqc.x(y[j])\n\tapply_QFT(qc, y)\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(-pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\treturn qc\n'''"}
{"problem": "QPC002_B8", "user": "A8433E17B2CF5", "submission_order": 2, "result": "RE", "execution_time": "1757 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumRegister, QuantumCircuit\n\n# Let n = len(qubits)\n# if no ctrl_qubits, adds 2 * len(qubits) circuit depth\n# otherwise,\n#  if n % 2 == 0, adds n * (n/2 + 1) circuit depth\n#  otherwise, adds (n-1) * ((n-1)/2 + 1) + n circuit depth\ndef apply_QFT(qc, qubits, ctrl_qubit = None, inverse = False):\n\tfrom numpy import pi\n\tcoef = -pi if inverse else pi\n\tif ctrl_qubit:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.ch(ctrl_qubit, qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.mcp(coef / 2**(i - j), [ctrl_qubit, qubits[j]], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.cswap(ctrl_qubit, qubits[i], qubits[len(qubits) - 1 - i])\n\telse:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.h(qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.cp(coef / 2**(i - j), qubits[j], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.swap(qubits[i], qubits[len(qubits) - 1 - i])\n\treturn qc\n\ndef solve(n, m, L, s, theta) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(m)\n\tqc = QuantumCircuit(x, y)\n\tfrom numpy import pi\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tapply_QFT(qc, y, inverse = True)\n\tif m == 1:\n\t\tif L == 0:\n\t\t\tqc.x(y[0])\n\t\tqc.p(theta)\n\t\tif L == 0:\n\t\t\tqc.x(y[0])\n\telse:\n\t\tfor j in range(m):\n\t\t\tif ~L >> j & 1:\n\t\t\t\tqc.x(y[j])\n\t\tqc.mcp(theta, list(range(m - 1)), m - 1)\n\t\tfor j in range(m):\n\t\t\tif ~L >> j & 1:\n\t\t\t\tqc.x(y[j])\n\tapply_QFT(qc, y)\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(-pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\treturn qc\n'''"}
{"problem": "QPC002_B8", "user": "A8433E17B2CF5", "submission_order": 3, "result": "WA", "execution_time": "2387 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumRegister, QuantumCircuit\n\n# Let n = len(qubits)\n# if no ctrl_qubits, adds 2 * len(qubits) circuit depth\n# otherwise,\n#  if n % 2 == 0, adds n * (n/2 + 1) circuit depth\n#  otherwise, adds (n-1) * ((n-1)/2 + 1) + n circuit depth\ndef apply_QFT(qc, qubits, ctrl_qubit = None, inverse = False):\n\tfrom numpy import pi\n\tcoef = -pi if inverse else pi\n\tif ctrl_qubit:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.ch(ctrl_qubit, qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.mcp(coef / 2**(i - j), [ctrl_qubit, qubits[j]], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.cswap(ctrl_qubit, qubits[i], qubits[len(qubits) - 1 - i])\n\telse:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.h(qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.cp(coef / 2**(i - j), qubits[j], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.swap(qubits[i], qubits[len(qubits) - 1 - i])\n\treturn qc\n\ndef solve(n, m, L, s, theta) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(m)\n\tqc = QuantumCircuit(x, y)\n\tfrom numpy import pi\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tapply_QFT(qc, y, inverse = True)\n\tif m == 1:\n\t\tif L == 0:\n\t\t\tqc.x(y[0])\n\t\tqc.p(theta, y[0])\n\t\tif L == 0:\n\t\t\tqc.x(y[0])\n\telse:\n\t\tfor j in range(m):\n\t\t\tif ~L >> j & 1:\n\t\t\t\tqc.x(y[j])\n\t\tqc.mcp(theta, list(range(m - 1)), m - 1)\n\t\tfor j in range(m):\n\t\t\tif ~L >> j & 1:\n\t\t\t\tqc.x(y[j])\n\tapply_QFT(qc, y)\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(-pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\treturn qc\n'''"}
{"problem": "QPC002_B8", "user": "A8433E17B2CF5", "submission_order": 4, "result": "AC", "execution_time": "2898 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumRegister, QuantumCircuit\n\n# Let n = len(qubits)\n# if no ctrl_qubits, adds 2 * len(qubits) circuit depth\n# otherwise,\n#  if n % 2 == 0, adds n * (n/2 + 1) circuit depth\n#  otherwise, adds (n-1) * ((n-1)/2 + 1) + n circuit depth\ndef apply_QFT(qc, qubits, ctrl_qubit = None, inverse = False):\n\tfrom numpy import pi\n\tcoef = -pi if inverse else pi\n\tif ctrl_qubit:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.ch(ctrl_qubit, qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.mcp(coef / 2**(i - j), [ctrl_qubit, qubits[j]], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.cswap(ctrl_qubit, qubits[i], qubits[len(qubits) - 1 - i])\n\telse:\n\t\tfor i in reversed(range(len(qubits))):\n\t\t\tqc.h(qubits[i])\n\t\t\tfor j in reversed(range(i)):\n\t\t\t\tqc.cp(coef / 2**(i - j), qubits[j], qubits[i])\n\t\tfor i in range(len(qubits) // 2):\n\t\t\tqc.swap(qubits[i], qubits[len(qubits) - 1 - i])\n\treturn qc\n\ndef solve(n, m, L, s, theta) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(m)\n\tqc = QuantumCircuit(x, y)\n\tfrom numpy import pi\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tapply_QFT(qc, y, inverse = True)\n\tif m == 1:\n\t\tif L == 0:\n\t\t\tqc.x(y[0])\n\t\tqc.p(theta, y[0])\n\t\tif L == 0:\n\t\t\tqc.x(y[0])\n\telse:\n\t\tfor j in range(m):\n\t\t\tif ~L >> j & 1:\n\t\t\t\tqc.x(y[j])\n\t\tqc.mcp(theta, y[:m - 1], y[m - 1])\n\t\tfor j in range(m):\n\t\t\tif ~L >> j & 1:\n\t\t\t\tqc.x(y[j])\n\tapply_QFT(qc, y)\n\tfor i in range(n):\n\t\tfor j in range(m):\n\t\t\tqc.cp(-pi * s[i] / 2**(m - 1 - j), x[i], y[j])\n\tfor j in range(m):\n\t\tqc.h(y[j])\n\treturn qc\n'''"}
{"problem": "QPC002_B8", "user": "A853740AD829B", "submission_order": 1, "result": "RE", "execution_time": "1379 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # Compute the function f(x) using controlled additions\n    for i in range(n):\n        if S[i] != 0:\n            for j in range(m):\n                if (S[i] >> j) & 1:\n                    qc.cx(x[i], y[j])\n    \n    # Create the comparison register\n    comparison = QuantumRegister(m, 'comparison')\n    qc.add_register(comparison)\n    \n    # Initialize the comparison register to the value L\n    for j in range(m):\n        if (L >> j) & 1:\n            qc.x(comparison[j])\n    \n    # Apply a controlled phase shift based on the comparison\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], comparison[j])\n    \n    # Apply phase shift based on comparison\n    qc.append(QuantumCircuit(m).compose(QuantumCircuit(m, name='phase_shift'), inplace=False), comparison)\n    qc.rz(2 * np.pi * theta, comparison)    \n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A853740AD829B", "submission_order": 2, "result": "UGE", "execution_time": "1200 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # Compute the function f(x) using controlled additions\n    for i in range(n):\n        if S[i] != 0:\n            for j in range(m):\n                if (S[i] >> j) & 1:\n                    qc.cx(x[i], y[j])\n    \n    # Create the comparison register\n    comparison = QuantumRegister(m, 'comparison')\n    qc.add_register(comparison)\n    \n    # Initialize the comparison register to the value L\n    for j in range(m):\n        if (L >> j) & 1:\n            qc.x(comparison[j])\n    \n    # Apply a controlled phase shift based on the comparison\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], comparison[j])\n    \n    # Apply phase shift based on comparison\n    qc.append(QuantumCircuit(m).compose(QuantumCircuit(m, name='phase_shift'), inplace=False), comparison)\n    qc.rz(2 * np.pi * theta, comparison)    \n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A853740AD829B", "submission_order": 3, "result": "RE", "execution_time": "1081 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(2**n):\n        # Compute f(x) for the current x\n        f_x = sum(S[j] * ((i >> j) & 1) for j in range(n))\n        f_x_mod = f_x % (2**m)\n        \n        # Apply phase shift if f(x) == L (mod 2^m)\n        if f_x_mod == L:\n            # Apply phase shift to |x⟩ and |0⟩ (for simplicity, we use the gate directly)\n            angle = 2 * np.pi * theta / (2 ** m)\n            qc.u1(angle, y[0])  # Apply phase shift to the first qubit in y\n            # Note: This is a simplified example. For a full implementation, controlled phase operations are needed.\n            \n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 1, "result": "WA", "execution_time": "1203 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Compute f(x) in the y register\n    for i in range(n):\n        for j in range(m):\n            if (S[i] & (1 << j)) != 0:\n                qc.cx(x[i], y[j])\n    \n    # Step 2: Compare f(x) with L\n    for j in range(m):\n        if (L & (1 << j)) == 0:\n            qc.x(y[j])\n    \n    # Step 3: Apply controlled phase rotation\n    qc.mcry(theta, y[:], x[n-1])\n    \n    # Step 4: Uncompute steps 2 and 1\n    for j in range(m):\n        if (L & (1 << j)) == 0:\n            qc.x(y[j])\n    \n    for i in range(n-1, -1, -1):\n        for j in range(m-1, -1, -1):\n            if (S[i] & (1 << j)) != 0:\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 2, "result": "WA", "execution_time": "1112 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    # Step 1: Compute f(x) in the y register\n    for i in range(n):\n        for j in range(m):\n            if (S[i] & (1 << j)) != 0:\n                qc.cx(x[i], y[j])\n    \n    # Step 2: Compare f(x) with L\n    for j in range(m):\n        if (L & (1 << j)) == 0:\n            qc.x(y[j])\n    \n    # Step 3: Apply controlled phase rotation\n    qc.mcry(theta, y[:], x[n-1])\n    \n    # Step 4: Uncompute steps 2 and 1\n    for j in range(m):\n        if (L & (1 << j)) == 0:\n            qc.x(y[j])\n    \n    for i in range(n-1, -1, -1):\n        for j in range(m-1, -1, -1):\n            if (S[i] & (1 << j)) != 0:\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 3, "result": "RE", "execution_time": "1233 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(m, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Compute f(x) = S0*x0 + S1*x1 + ... + Sn-1*xn-1\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    \n    # Step 2: Compare f(x) mod 2^m with L\n    L_bin = format(L, f'0{m}b')\n    for j in range(m):\n        if L_bin[j] == '0':\n            qc.x(y[j])\n    \n    # Step 3: Apply the phase shift theta if comparison is successful\n    qc.mcx(y, y[0])  # Multi-controlled X gate on ancilla to check if f(x) == L mod 2^m\n    qc.p(theta, y[0])  # Apply the phase shift\n    \n    # Step 4: Reverse the comparison operation to uncompute ancilla qubits\n    qc.mcx(y, y[0])\n    \n    # Reverse Step 2\n    for j in range(m):\n        if L_bin[j] == '0':\n            qc.x(y[j])\n    \n    # Reverse Step 1: Uncompute f(x)\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 4, "result": "QLE", "execution_time": "1497 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(m, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Compute f(x) = S0*x0 + S1*x1 + ... + Sn-1*xn-1\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    \n    # Step 2: Compare f(x) mod 2^m with L\n    L_bin = format(L, f'0{m}b')\n    for j in range(m):\n        if L_bin[j] == '0':\n            qc.x(y[j])\n    \n    # Step 3: Apply the phase shift theta if comparison is successful\n    # Use an ancilla qubit for the multi-controlled phase shift\n    if m > 1:\n        ancilla = QuantumRegister(1, 'ancilla')\n        qc.add_register(ancilla)\n        qc.mcx(y, ancilla[0])  # Multi-controlled X gate to check if f(x) == L mod 2^m\n        qc.p(theta, ancilla[0])  # Apply the phase shift\n        qc.mcx(y, ancilla[0])  # Uncompute the ancilla\n    else:\n        qc.p(theta, y[0])  # For m=1, we directly apply the phase shift without ancilla\n    \n    # Step 4: Reverse the comparison operation to uncompute ancilla qubits\n    for j in range(m):\n        if L_bin[j] == '0':\n            qc.x(y[j])\n    \n    # Reverse Step 1: Uncompute f(x)\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 5, "result": "RE", "execution_time": "1282 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(m, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Compute f(x) = S0*x0 + S1*x1 + ... + Sn-1*xn-1\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    \n    # Step 2: Compare f(x) mod 2^m with L\n    L_bin = format(L, f'0{m}b')\n    for j in range(m):\n        if L_bin[j] == '0':\n            qc.x(y[j])\n    \n    # Step 3: Apply the phase shift theta if comparison is successful\n    qc.mcx(y[:-1], y[-1])  # Multi-controlled X gate on y[0:m-1] controlling y[m-1]\n    qc.p(theta, y[-1])     # Apply the phase shift to the last qubit in y register\n    qc.mcx(y[:-1], y[-1])  # Uncompute the mcx operation\n    \n    # Step 4: Reverse the comparison operation to uncompute ancilla qubits\n    for j in range(m):\n        if L_bin[j] == '0':\n            qc.x(y[j])\n    \n    # Reverse Step 1: Uncompute f(x)\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 6, "result": "RE", "execution_time": "1050 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(m, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Calculate f(x) = S0*x0 + S1*x1 + ... + Sn-1*xn-1\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n    \n    # Step 2: Apply an X gate to y qubits where L has a 0 in the binary representation\n    L_bin = format(L, f'0{m}b')\n    for j in range(m):\n        if L_bin[j] == '0':\n            qc.x(y[j])\n    \n    # Step 3: Apply the phase shift theta if f(x) == L (mod 2^m)\n    qc.mcx(list(y), y[0])  # Multi-controlled X gate on all y qubits controlling y[0]\n    qc.p(theta, y[0])      # Apply the phase shift to y[0] if the condition is satisfied\n    qc.mcx(list(y), y[0])  # Uncompute the mcx operation to maintain reversibility\n    \n    # Step 4: Reverse the X gates to restore y qubits to their original state\n    for j in range(m):\n        if L_bin[j] == '0':\n            qc.x(y[j])\n    \n    # Step 5: Reverse the computation of f(x) by applying CX gates again\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 7, "result": "WA", "execution_time": "1166 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # Calculate the target value of f(x)\n    target_value = L % (2 ** m)\n    \n    # Add a quantum phase oracle\n    # This requires applying controlled phase shifts based on S\n    for i in range(n):\n        if S[i] != 0:\n            qc.cx(x[i], y[0])  # Example, use controlled-X gates here as placeholders\n    \n    # Apply a conditional phase gate\n    # We need to encode the function and apply the phase based on the result\n    qc.append(\n        # Replace with actual implementation\n        # Controlled phase gate applying e^{i*theta} if f(x) == L (mod 2^m)\n        QuantumCircuit(m).to_gate().control(n),\n        [*x, *y]\n    )\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 8, "result": "WA", "execution_time": "1313 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x = QuantumRegister(n, name='x')\n    y = QuantumRegister(m, name='y')\n    qc = QuantumCircuit(x, y)\n    \n    # Calculate f(x) = S0 * x0 + S1 * x1 + ... + Sn-1 * xn-1\n    # Encode the phase flip for f(x) = L mod 2^m\n    \n    # Define the value to compare against\n    target_value = L % (2 ** m)\n    \n    # Add phase flip for f(x) == target_value\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:  # Check if the j-th bit of S[i] is 1\n                qc.cx(x[i], y[j])  # Controlled-X gate\n    \n    # Apply the conditional phase shift\n    # We will use a phase flip if f(x) == target_value\n    for k in range(m):\n        if ((target_value >> k) & 1) == 1:\n            qc.rz(2 * theta, y[k])  # Apply the phase shift to the y register\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 9, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit import Gate\nfrom qiskit.circuit.library import ZGate, PhaseGate, U1\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    \n    # Define the function f(x) using an auxiliary qubit\n    aux = QuantumRegister(1)\n    qc.add_register(aux)\n    \n    # Apply the controlled operations to implement f(x) = L\n    # Create the controlled addition circuit\n    qc.add_register(QuantumRegister(n + m + 1))\n    \n    # Apply the controlled addition\n    for i in range(n):\n        if S[i] != 0:\n            qc.cx(x[i], aux[0])  # Controlled NOT gate (used for addition)\n            qc.rz(2 * S[i] * theta, aux[0])\n    \n    # Apply the phase gate to |x⟩_n |0⟩_m if f(x) = L\n    qc.append(PhaseGate(theta), [aux[0]])\n    \n    # Clean up: Remove auxiliary qubit\n    qc.remove_register(aux)\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 10, "result": "RE", "execution_time": "1091 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x = QuantumRegister(n, name='x')\n    y = QuantumRegister(m, name='y')\n    qc = QuantumCircuit(x, y)\n    \n    # Adding an ancillary qubit for the phase application\n    aux = QuantumRegister(1, name='aux')\n    qc.add_register(aux)\n    \n    # Initialize auxiliary qubit to |1>\n    qc.x(aux[0])\n    \n    # Apply the addition of S coefficients\n    for i in range(n):\n        if S[i] != 0:\n            # Apply a controlled-phase gate to simulate the effect of S[i]\n            qc.cp(2 * np.pi * S[i] / (2**m), x[i], aux[0])\n    \n    # Apply the phase gate based on theta\n    qc.append(PhaseGate(theta), [aux[0]])\n    \n    # Clean up: Remove auxiliary qubit\n    qc.remove_register(aux)\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 11, "result": "RE", "execution_time": "1173 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    # Define quantum registers\n    x = QuantumRegister(n, name='x')  # Input register\n    y = QuantumRegister(m, name='y')  # Output register\n    \n    # Create quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # To implement f(x) = S0*x0 + S1*x1 + ... + Sn-1*xn-1 (mod 2^m)\n    # Use an additional auxiliary qubit for phase application\n    aux = QuantumRegister(1, name='aux')\n    qc.add_register(aux)\n    \n    # Initialize auxiliary qubit to |1>\n    qc.x(aux[0])\n    \n    # Apply the function f(x) as controlled addition\n    for i in range(n):\n        if S[i] != 0:\n            for j in range(m):\n                # Apply controlled addition for each bit of y\n                qc.cu1(np.pi * S[i] / (2 ** j), x[i], y[j])\n    \n    # Apply phase shift if f(x) = L (mod 2^m)\n    qc.append(QuantumCircuit(*y, *aux).u1(theta, aux[0]), [aux[0]])\n    \n    # Clean up: Remove auxiliary qubit\n    qc.remove_register(aux)\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 12, "result": "RE", "execution_time": "1246 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x = QuantumRegister(n, name='x')\n    y = QuantumRegister(m, name='y')\n    qc = QuantumCircuit(x, y)\n    \n    # Define the auxiliary qubit\n    aux = QuantumRegister(1, name='aux')\n    qc.add_register(aux)\n    \n    # Initialize auxiliary qubit to |1>\n    qc.x(aux[0])\n    \n    # Apply the function f(x) using controlled-phase gates\n    # To simulate f(x) mod 2^m using controlled gates\n    for i in range(n):\n        if S[i] != 0:\n            for j in range(m):\n                qc.cx(x[i], y[j])  # Apply controlled X gates\n                qc.rz(2 * np.pi * S[i] / (2**m), y[j])  # Apply rotation for phase\n    \n    # Apply phase shift theta if f(x) = L (mod 2^m)\n    qc.append(PhaseGate(theta), [aux[0]])\n    \n    # Clean up auxiliary qubit\n    qc.remove_register(aux)\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A85FB03577243", "submission_order": 13, "result": "RE", "execution_time": "1189 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import MCXGate, PhaseGate\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    # Quantum registers\n    x = QuantumRegister(n, name='x')\n    y = QuantumRegister(m, name='y')\n    qc = QuantumCircuit(x, y)\n\n    # Create an additional auxiliary qubit for phase application\n    aux = QuantumRegister(1, name='aux')\n    qc.add_register(aux)\n    \n    # Initialize auxiliary qubit to |1>\n    qc.x(aux[0])\n    \n    # Apply the function f(x) = S0*x0 + S1*x1 + ... + Sn-1*xn-1 mod 2^m\n    # Here we use controlled additions to accumulate the result in the y register\n    for i in range(n):\n        if S[i] != 0:\n            for j in range(m):\n                qc.cx(x[i], y[j])\n                qc.rz(2 * np.pi * S[i] / (2 ** j), y[j])\n    \n    # Apply phase shift if f(x) = L mod 2^m\n    phase_shift = np.exp(1j * theta)\n    for k in range(m):\n        if (L >> k) & 1:\n            qc.cx(aux[0], y[k])\n            qc.p(theta, y[k])\n    \n    # Cleanup: Remove auxiliary qubit\n    qc.remove_register(aux)\n    \n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "A94F6F425C58C", "submission_order": 1, "result": "RE", "execution_time": "1317 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # Step 1: Compute f(x) and store in y register\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n\n    # Step 2: Apply modular addition of L to the y register\n    for j in range(m):\n        if (L >> j) & 1:\n            qc.x(y[j])\n    \n    # Step 3: Apply the controlled phase shift based on whether y equals 0 (i.e., f(x) = L mod 2^m)\n    qc.append(QFT(m, do_swaps=False).inverse(), y)  # Apply inverse QFT to y\n    qc.mcx(list(y), y[0])  # Apply multi-controlled X gate if y is in |0>\n    qc.u1(theta, y[0])  # Apply phase shift of theta\n    qc.mcx(list(y), y[0])  # Uncompute the multi-controlled X gate\n    qc.append(QFT(m, do_swaps=False), y)  # Apply QFT to return y to original state\n\n    # Step 4: Undo the modular addition of L\n    for j in range(m):\n        if (L >> j) & 1:\n            qc.x(y[j])\n    \n    # Step 5: Uncompute f(x) from y register\n    for i in range(n):\n        for j in range(m):\n            if (S[i] >> j) & 1:\n                qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 1, "result": "RE", "execution_time": "1353 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef r(qc:QuantumCircuit, ctrl:int, targ:int, l:int):\n    angle = 2*math.pi(1<<l), ctrl, targ\n    qc.cp(angle, ctrl,targ)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1,i)\n        qc.cx(i,n-i-1)\n    for i in range(0,n):\n        qc.h(i)\n        for j in range(1, n-1):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef B_6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for i in range(m):\n        for j in range(n):\n            theta = 2*math.pi*S[j]/(1<<m)*(1<<i)\n            qc.cp(theta, y[i], x[j])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef B_2(n:int, L:int, theta:float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c= n*[0]\n    for a in range(n):\n        b[a]=L%2\n        L//=2\n    for d in range(n):\n        if b[d]==0:\n            qc.x(d)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(B_6(n, m, S))\n    qc = qc.compose(B_2(m, L, theta), y)\n    qc = qc.compose(B_6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 2, "result": "RE", "execution_time": "1101 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef r(qc:QuantumCircuit, ctrl:int, targ:int, l:int):\n    angle = 2*math.pi(1<<l), ctrl, targ\n    qc.cp(angle, ctrl,targ)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1,i)\n        qc.cx(i,n-i-1)\n    for i in range(0,n):\n        qc.h(i)\n        for j in range(1, n-1):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef B_6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for i in range(m):\n        for j in range(n):\n            theta = 2*math.pi*S[j]/(1<<m)*(1<<i)\n            qc.cp(theta, y[i], x[j])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef B_2(n:int, L:int, theta:float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c= n*[0]\n    for a in range(n):\n        c[a]=L%2\n        L//=2\n    for d in range(n):\n        if c[d]==0:\n            qc.x(d)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if c[i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(B_6(n, m, S))\n    qc = qc.compose(B_2(m, L, theta), y)\n    qc = qc.compose(B_6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 3, "result": "RE", "execution_time": "1528 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef r(qc:QuantumCircuit, ctrl:int, targ:int, l:int):\n    angle = 2*math.pi(1<<l)\n    qc.cp(angle, ctrl,targ)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1,i)\n        qc.cx(i,n-i-1)\n    for i in range(0,n):\n        qc.h(i)\n        for j in range(1, n-1):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef B_6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for i in range(m):\n        for j in range(n):\n            theta = 2*math.pi*S[j]/(1<<m)*(1<<i)\n            qc.cp(theta, y[i], x[j])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef B_2(n:int, L:int, theta:float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c= n*[0]\n    for a in range(n):\n        c[a]=L%2\n        L//=2\n    for d in range(n):\n        if c[d]==0:\n            qc.x(d)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if [i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(B_6(n, m, S))\n    qc = qc.compose(B_2(m, L, theta), y)\n    qc = qc.compose(B_6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 4, "result": "RE", "execution_time": "1470 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef r(qc:QuantumCircuit, ctrl:int, targ:int, l:int):\n    angle = 2*math.pi(1<<l)\n    qc.cp(angle, ctrl,targ)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1,i)\n        qc.cx(i,n-i-1)\n    for i in range(0,n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef B_6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for i in range(m):\n        for j in range(n):\n            theta = 2*math.pi*S[j]/(1<<m)*(1<<i)\n            qc.cp(theta, y[i], x[j])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef B_2(n:int, L:int, theta:float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c= n*[0]\n    for a in range(n):\n        c[a]=L%2\n        L//=2\n    for d in range(n):\n        if c[d]==0:\n            qc.x(d)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if [i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(B_6(n, m, S))\n    qc = qc.compose(B_2(m, L, theta), y)\n    qc = qc.compose(B_6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 5, "result": "RE", "execution_time": "1137 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef r(qc:QuantumCircuit, control:int, target:int, l:int):\n    angle = 2*math.pi(1<<l)\n    qc.cp(angle, control, target)\n\ndef qft(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef B_6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for i in range(m):\n        for j in range(n):\n            qc.cp(2*math.pi*S[j]/(1<<m)*(1<<i), y[i], x[j])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef B_2(n:int, L:int, theta:float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c= [0]*n\n    for a in range(n):\n        c[a]=L%2\n        L//=2\n    for a in range(n):\n        if c[a]==0:\n            qc.x(a)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if [i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(B_6(n, m, S))\n    qc = qc.compose(B_2(m, L, theta), y)\n    qc = qc.compose(B_6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 6, "result": "RE", "execution_time": "1110 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    angle = 2*math.pi(1<<l)\n    qc.cp(angle, control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef B_6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for i in range(m):\n        for j in range(n):\n            qc.cp(2*math.pi*S[j]/(1<<m)*(1<<i), y[i], x[j])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef B_2(n:int, L:int, theta:float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c= [0]*n\n    for a in range(n):\n        c[a]=L%2\n        L//=2\n    for a in range(n):\n        if c[a]==0:\n            qc.x(a)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if [i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(B_6(n, m, S))\n    qc = qc.compose(B_2(m, L, theta), y)\n    qc = qc.compose(B_6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 7, "result": "RE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    #angle = 2*math.pi(1<<l)\n    qc.cp(2*math.pi(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef b2(n:int, L:int, theta:float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c= [0]*n\n    for a in range(n):\n        c[a]=L%2\n        L//=2\n    for a in range(n):\n        if c[a]==0:\n            qc.x(a)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if [i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(m, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 8, "result": "RE", "execution_time": "1243 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    #angle = 2*math.pi(1<<l)\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(m, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 9, "result": "RE", "execution_time": "1096 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    angle = 2*math.pi(1<<l)\n    qc.cp(angle, control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for i in range(m):\n        for j in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<i), y[i], x[j])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    c=[0]*n\n    for i in range(n):\n        c[i]=L%2\n        L//=2\n    for i in range(n):\n        if c[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if c[i]==0:\n            qc.x(i)\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(m, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 10, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    #angle = 2*math.pi(1<<l)\n    qc.cp(2*math.pi(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k, y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(m, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 11, "result": "RE", "execution_time": "1446 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    #angle = 2*math.pi(1<<l)\n    qc.cp(2*math.pi(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n:int, m:int, S:list[int]) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(m)\n    qc = QuantumCircuit(x,y)\n\n    #Appy superposition gate on y-reg\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n    \n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n    \n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(m, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB316C6E051C5", "submission_order": 12, "result": "AC", "execution_time": "1769 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(m, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AB9B56579FC8B", "submission_order": 1, "result": "AC", "execution_time": "2032 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef B2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (L>>i & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if not (L>>i & 1):\n            qc.x(i)\n    return qc\n\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\ndef IQFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(-math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(y[j])\n        # Oracle B5\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]*2**j/2**m, y[j], x[i])    \n    # IQFT\n    qc.compose(IQFT(m), y, inplace=True)\n\n    qc.compose(B2(m, L, theta), y, inplace=True)\n\n    # QFT\n    qc.compose(QFT(m), y, inplace=True)\n\n    for j in range(m):\n        # Oracle B5(minus)\n        for i in range(n):\n            qc.cp(-2*math.pi*S[i]*2**j/2**m, y[j], x[i])\n        \n    # IQFT\n    qc.compose(IQFT(m), y, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AC1650E285B52", "submission_order": 1, "result": "WA", "execution_time": "1933 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(n, L, theta))\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AC1650E285B52", "submission_order": 2, "result": "RE", "execution_time": "1570 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(n, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AC1650E285B52", "submission_order": 3, "result": "AC", "execution_time": "2288 ms", "memory": "184 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef r(qc: QuantumCircuit, control: int, target: int, l: int):\n    qc.cp(2*math.pi/(1<<l), control, target)\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n        qc.cx(n-i-1, i)\n        qc.cx(i, n-i-1)\n    for i in range(0, n):\n        qc.h(i)\n        for j in range(1, n-i):\n            r(qc, i+j, i, j+1)\n    return qc\n\ndef b6(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    for k in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(1<<m)*(1<<k), y[k], x[i])\n    qc = qc.compose(qft(m).inverse(), y)\n\n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    b=[0]*n\n    for i in range(n):\n        b[i]=L%2\n        L//=2\n    for i in range(n):\n        if b[i]==0:\n            qc.x(i)\n    if n>1:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    else:\n        qc.p(theta, 0)\n    for i in reversed(range(n)):\n        if b[i]==0:\n            qc.x(i)\n\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(b6(n, m, S))\n    qc = qc.compose(b2(m, L, theta), y)\n    qc = qc.compose(b6(n, m, S).inverse())\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AD5F3F54E09FE", "submission_order": 1, "result": "RE", "execution_time": "1082 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\n\ndef PS_oracle(n, L, theta):\n    \n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #   qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if n > 1:\n\n        if ctrl_state[0] == '0':\n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.x(0)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n            qc.x(0)\n        \n        else : \n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    #qc.measure_all()\n    else :\n        if L == 0:\n            qc.x(0)\n        qc.p(theta , 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\n\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    qc = qc.compose(PS_oracle(m, L, theta), y)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AD5F3F54E09FE", "submission_order": 2, "result": "WA", "execution_time": "1252 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nimport numpy as np\n\n\n\ndef PS_oracle(n, L, theta):\n    \n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #   qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if n > 1:\n\n        if ctrl_state[0] == '0':\n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.x(0)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n            qc.x(0)\n        \n        else : \n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    #qc.measure_all()\n    else :\n        if L == 0:\n            qc.x(0)\n        qc.p(theta , 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\n\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    qc = qc.compose(PS_oracle(m, L, theta), y)\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AD5F3F54E09FE", "submission_order": 3, "result": "WA", "execution_time": "1421 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nimport numpy as n\n\n\n\ndef PS_oracle(n, L, theta):\n    \n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #   qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if n > 1:\n\n        if ctrl_state[0] == '0':\n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.x(0)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n            qc.x(0)\n        \n        else : \n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    #qc.measure_all()\n    else :\n        if L == 0:\n            qc.x(0)\n        qc.p(theta , 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\n\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    qc = qc.compose(PS_oracle(m, L, theta), y)\n\n    qc = qc.compose(qft(m), y)\n\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = -2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc.h(y)\n\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AD5F3F54E09FE", "submission_order": 4, "result": "WA", "execution_time": "1016 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nimport numpy as n\n\n\n\ndef PS_oracle(n, L, theta):\n    \n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #for i in range(n):\n    #   qc.h(i)\n    \n    binary = bin(L)\n    ctrl_state = binary[-1:1:-1]\n    \n    print(ctrl_state)\n\n    ctrl_state = ctrl_state + (n - len(ctrl_state))*'0' \n    print(ctrl_state)\n\n    print(ctrl_state[0])\n\n    if n > 1:\n\n        if ctrl_state[0] == '0':\n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.x(0)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n            qc.x(0)\n        \n        else : \n            ctrl_state = ctrl_state[-1:0:-1]\n            print(ctrl_state)\n            qc.mcp(theta, control_qubits= [i for i in range(1,n)] , ctrl_state = ctrl_state,target_qubit= 0)\n\n    #qc.measure_all()\n    else :\n        if L == 0:\n            qc.x(0)\n        qc.p(theta , 0)\n        if L == 0:\n            qc.x(0)\n\n    return qc\n\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1+n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n-1-idx)\n        for jdx in range(idx+1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n-1-jdx, n-1-idx)\n\n    for idx in range(0, n//2):\n        qc.swap(idx, n-idx-1)\n\n    return qc\n\n\n\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = 2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n    qc = qc.compose(PS_oracle(m, L, theta), y)\n\n    qc = qc.compose(qft(m), y)\n\n    for idx in range(0, n):\n        for jdx in range(0, m):\n            theta = -2 * math.pi * S[idx] * (2**jdx) / (2**m)\n            qc.cp(theta, x[idx], y[jdx])\n\n    qc = qc.compose(qft(m).inverse(), y)\n\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AD5F3F54E09FE", "submission_order": 5, "result": "AC", "execution_time": "1749 ms", "memory": "183 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\nfrom qiskit import QuantumCircuit\n\n\ndef B2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if not (L>>i & 1):\n            qc.x(i)\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if not (L>>i & 1):\n            qc.x(i)\n    return qc\n\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\ndef IQFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(n-i-1)\n        for j in range(1, n-i):\n            qc.cp(-math.pi/2**j, n-i-j-1, n-i-1)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for j in range(m):\n        qc.h(y[j])\n        # Oracle B5\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]*2**j/2**m, y[j], x[i])    \n    # IQFT\n    qc.compose(IQFT(m), y, inplace=True)\n\n    qc.compose(B2(m, L, theta), y, inplace=True)\n\n    # QFT\n    qc.compose(QFT(m), y, inplace=True)\n\n    for j in range(m):\n        # Oracle B5(minus)\n        for i in range(n):\n            qc.cp(-2*math.pi*S[i]*2**j/2**m, y[j], x[i])\n        \n    # IQFT\n    qc.compose(IQFT(m), y, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AD70A27E32943", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit import Gate\nimport numpy as np\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    def compute_f(x_state):\n        return sum(S[i] * int(x_state[i]) for i in range(n))\n\n    # Iterate over all possible states for the n qubits\n    for i in range(2 ** n):\n        x_state = [int(bit) for bit in format(i, f'0{n}b')]\n        f_x = compute_f(x_state)\n        f_x_mod = f_x % (2 ** m)\n\n        # Apply the phase based on the condition\n        if f_x_mod == L:\n            # Apply phase shift\n            qc.u1(theta, y[0])  # Applying phase gate U1 is equivalent to exp(i*theta) for one qubit\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "AD70A27E32943", "submission_order": 2, "result": "RE", "execution_time": "1317 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        for j in range(m):\n            angle = pi * S[i] / (2**j)\n            qc.cu1(angle, i, n+j)\n\n    # Compare f(x) with L (mod 2^m)\n    # ... (Implement comparison logic here)\n\n    # Apply phase shift if f(x) = L (mod 2^m)\n    # ... (Implement controlled phase gate based on comparison result)\n\n    return qc\n'''"}
{"problem": "QPC002_B8", "user": "ADCDAC93A4034", "submission_order": 1, "result": "AC", "execution_time": "1871 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n# from qiskit.quantum_info import Statevector\n\ndef quantum_fourier_transform(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(i-1, -1, -1):\n            qc.cp(2*math.pi/(2**(i-j+1)), j, i)\n    \n    i = 0\n    while i<n-i-1:\n        qc.swap(i, n-i-1)\n        i += 1\n    \n    return qc\n\ndef b7(n: int, m: int, S: list[int]) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n    qc.compose(quantum_fourier_transform(m), y, inplace=True)\n    for j in range(m):\n        for i in range(n):\n            qc.cp(2*math.pi*S[i]/(2**m)*(2**j), x[i], y[j])\n    qc.compose(quantum_fourier_transform(m).inverse(), y, inplace=True)\n\n    return qc\n\ndef b2(n: int, L: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        if ((L>>i)&1)==0:\n            qc.x(i)\n    if n==1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n-1)), n-1)\n    for i in range(n):\n        if ((L>>i)&1)==0:\n            qc.x(i)\n    return qc\n\ndef solve(n: int, m: int, L: int, S: list[int], theta: float) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(m)\n    qc = QuantumCircuit(x, y)\n\n    # init = [0]*(2**(n+m))\n    # init[3] = 1\n    # qc.initialize(init)\n\n    # Write your code here:\n\n    qc.compose(b7(n, m, S), inplace=True)\n    qc.compose(b2(m, L, theta), y, inplace=True)\n    qc.compose(b7(n, m, S).inverse(), inplace=True)\n\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2, 2, 3, [1, 2], 3.14159)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 1, "result": "RE", "execution_time": "1313 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    qc.x(range(n))\n\n    return qc\n\ndef compose(u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    u0 = U\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(u0, rs, rt)\n    u2 = compose(u1, rs, rt)\n    u3 = compose(u2, rs, rt)\n    u3 = compose(u2, rs, rt)\n\n    return u3\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 2, "result": "RE", "execution_time": "1214 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    u0 = U\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n\n    return u3\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 3, "result": "RE", "execution_time": "1083 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n\n    return u3\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 4, "result": "RE", "execution_time": "1105 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 5, "result": "WA", "execution_time": "2533 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi/3, 0)\n    else:\n        qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 6, "result": "WA", "execution_time": "1917 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi/3, 0)\n    else:\n        qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.5:\n        def UInv():\n            return U().inverse()\n\n        return solve(n, 1/P, UInv, R)\n\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 7, "result": "WA", "execution_time": "1264 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi/3, 0)\n    else:\n        qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.5:\n        return solve1(n, U, R)\n    else:\n        return solve2(n, U, R)\n\n# make w to 0, inverse\ndef solve1(n, U, R):\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4.inverse()\n\ndef solve2(n, U, R):\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rt, rs)\n    u2 = compose(n, u1, rt, rs)\n    u3 = compose(n, u2, rt, rs)\n    u4 = compose(n, u3, rt, rs)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 8, "result": "WA", "execution_time": "2732 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi/3, 0)\n    else:\n        qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.5:\n        return solve1(n, U, R)\n    else:\n        return solve2(n, U, R)\n\n# make w to 0, inverse\ndef solve1(n, U, R):\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rt, rs)\n    u2 = compose(n, u1, rt, rs)\n    u3 = compose(n, u2, rt, rs)\n    u4 = compose(n, u3, rt, rs)\n\n    return u4.inverse()\n\ndef solve2(n, U, R):\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 9, "result": "WA", "execution_time": "3355 ms", "memory": "147 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi/3, 0)\n    else:\n        qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 1.0/4:\n        return solve1(n, U, R)\n    else:\n        return solve2(n, U, R)\n\n# make w to 0, inverse\ndef solve1(n, U, R):\n    u0 = U().inverse()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rt, rs)\n    u2 = compose(n, u1, rt, rs)\n    u3 = compose(n, u2, rt, rs)\n    u4 = compose(n, u3, rt, rs)\n\n    return u4.inverse()\n\ndef solve2(n, U, R):\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 10, "result": "WA", "execution_time": "2520 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi/3, 0)\n    else:\n        qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.5:\n        return solve1(n, U, R)\n    else:\n        return solve2(n, U, R)\n\n# make w to 0, inverse\ndef solve1(n, U, R):\n    u0 = U().inverse()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rt, rs)\n    u2 = compose(n, u1, rt, rs)\n    u3 = compose(n, u2, rt, rs)\n    u4 = compose(n, u3, rt, rs)\n\n    return u4.inverse()\n\ndef solve2(n, U, R):\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 11, "result": "WA", "execution_time": "3121 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    if n == 1:\n        qc.p(math.pi/3, 0)\n    else:\n        qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 1/np.sqrt(2):\n        return solve1(n, U, R)\n    else:\n        return solve2(n, U, R)\n\n# make w to 0, inverse\ndef solve1(n, U, R):\n    u0 = U().inverse()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rt, rs)\n    u2 = compose(n, u1, rt, rs)\n    u3 = compose(n, u2, rt, rs)\n    u4 = compose(n, u3, rt, rs)\n\n    return u4.inverse()\n\ndef solve2(n, U, R):\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 12, "result": "WA", "execution_time": "2515 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(math.pi/3, 0)\n    else:\n        qc.mcp(math.pi/3, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    return solve1(n, U, R)\n    \n    if P < 0.5:\n        return solve1(n, U, R)\n    else:\n        return solve2(n, U, R)\n\n# make w to 0, inverse\ndef solve1(n, U, R):\n    u0 = U().inverse()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rt, rs)\n    u2 = compose(n, u1, rt, rs)\n    u3 = compose(n, u2, rt, rs)\n    u4 = compose(n, u3, rt, rs)\n\n    return u4.inverse()\n\ndef solve2(n, U, R):\n    u0 = U()\n    rs = get_rs(n)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 13, "result": "RE", "execution_time": "1337 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(theta, n):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    return solve1(n, U, R)\n    \n    if P < 0.5:\n        return solve1(n, U, R)\n    else:\n        return solve2(n, U, R)\n\n# make w to 0, inverse\ndef solve1(n, U, R):\n    u0 = U()\n    rs = get_rs(n, -math.pi/3)\n    rt = R(-math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n\ndef solve2(n, U, R):\n    u0 = U()\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 14, "result": "WA", "execution_time": "3042 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    return solve1(n, U, R)\n    \n    if P < 0.5:\n        return solve1(n, U, R)\n    else:\n        return solve2(n, U, R)\n\n# make w to 0, inverse\ndef solve1(n, U, R):\n    u0 = U()\n    rs = get_rs(n, -math.pi/3)\n    rt = R(-math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n\ndef solve2(n, U, R):\n    u0 = U()\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 15, "result": "RE", "execution_time": "1244 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    u0 = U()\n    rs = get_rs(n, math.pi/2)\n    rt = R(math.pi/2)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u0\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 16, "result": "WA", "execution_time": "1334 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    u0 = U()\n    rs = get_rs(n, math.pi/2)\n    rt = R(math.pi/2)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 17, "result": "DLE", "execution_time": "1269 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    u0 = U()\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n    u5 = compose(n, u4, rs, rt)\n\n    return u5\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 18, "result": "WA", "execution_time": "1976 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    u0 = U()\n    rs = R(math.pi/3)\n    rt = get_rs(n, math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4.inverse()\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 19, "result": "WA", "execution_time": "2057 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    u0 = U().inverse()\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 20, "result": "WA", "execution_time": "1580 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    u0 = QuantumCircuit(n)\n    u0.h(range(n))\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 21, "result": "WA", "execution_time": "1452 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    u0 = QuantumCircuit(n)\n    u0.ry(1, range(n))\n    u0.h(range(n))\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 22, "result": "WA", "execution_time": "1296 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.3:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 23, "result": "WA", "execution_time": "1492 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.2:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 24, "result": "WA", "execution_time": "1537 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.1:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 25, "result": "WA", "execution_time": "1537 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.1:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 26, "result": "WA", "execution_time": "3283 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if 0.4 < P < 0.5:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A068CD909CA26", "submission_order": 27, "result": "AC", "execution_time": "3121 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.05:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A0AA2A3E8DDBA", "submission_order": 1, "result": "RE", "execution_time": "1134 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply U to the initial state |0>\n    qc.compose(U(), inplace=True)\n    \n    # Calculate the optimal number of repetitions of R(θ)\n    # Grover-like amplification strategy\n    theta = np.arccos(np.sqrt(P))\n    k = int(np.round(np.pi / (4 * theta)))\n    \n    for _ in range(min(k, 100)):\n        qc.compose(R(2 * theta), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A390193FB3F99", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     qc.compose(U(), inplace=True)\n      theta = 2 * 3.141592653589793 * 0.5 \n    qc.compose(R(theta), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A390193FB3F99", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     qc.compose(U(), inplace=True)\n    \n    \n    theta = 2 * P \n    for _ in range(100):  \n        qc.compose(R(theta), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A390193FB3F99", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     ancilla_qubits = QuantumRegister(n)\n    qc.add_register(ancilla_qubits)\n\n    qc.compose(U(), inplace=True)\n\n    qc.append(QFTInverse(n), ancilla_qubits)\n\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A390193FB3F99", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import QFTInverse\n\ndef U():\n    \n    pass\n\ndef R(theta):\n \n    pass\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    ancilla_qubits = QuantumRegister(n)\n    qc.add_register(ancilla_qubits)\n\n    qc.compose(U(), inplace=True)\n\n    qc.append(QFTInverse(n), ancilla_qubits)\n\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A390193FB3F99", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import QFTInverse\n\ndef U():\n    #\n    pass\n\ndef R(theta):\n \n    pass\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    ancilla_qubits = QuantumRegister(n)\n    qc.add_register(ancilla_qubits)\n\n    qc.compose(U(), inplace=True)\n\n    qc.append(QFTInverse(n), ancilla_qubits)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A390193FB3F99", "submission_order": 6, "result": "RE", "execution_time": "1271 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.05:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A3D94D8C4B68A", "submission_order": 1, "result": "RE", "execution_time": "1594 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    \n    # Apply the R(θ) gate\n    theta = 2 * np.arccos(np.sqrt(P))  # Compute θ such that sin^2(θ/2) = P\n    qc.compose(R(theta), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A3D94D8C4B68A", "submission_order": 2, "result": "RE", "execution_time": "1081 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply the unitary gate U to the quantum circuit\n    qc.compose(U(), inplace=True)\n    \n    # Choose theta for the R(theta) gate to maximize overlap\n    theta = np.angle(1 - np.sqrt(P))  # Example choice, you may need to optimize this\n    \n    # Apply the parametric gate R(theta)\n    qc.compose(R(theta), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A3D94D8C4B68A", "submission_order": 3, "result": "WA", "execution_time": "1057 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply the unitary gate U to the quantum circuit\n    qc.compose(U(), inplace=True)\n    \n    # Choose theta for the R(theta) gate to maximize overlap\n    theta = np.angle(1 - np.sqrt(P))  # Example choice, you may need to optimize this\n    \n    # Apply the parametric gate R(theta)\n    qc.compose(R(theta), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A3D94D8C4B68A", "submission_order": 4, "result": "WA", "execution_time": "1071 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    \n    \n    theta = np.arccos(1 - P) * 2  # Derived from P for optimal θ\n    qc.compose(R(theta), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A4998B253E0BA", "submission_order": 1, "result": "WA", "execution_time": "1358 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, angle):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(angle, 0)\n    else:\n        qc.mcp(angle, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if P < 0.05:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A4998B253E0BA", "submission_order": 2, "result": "WA", "execution_time": "1347 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if P < 0.05:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A4998B253E0BA", "submission_order": 3, "result": "AC", "execution_time": "3176 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.05:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A6DEA4F1DEC2B", "submission_order": 1, "result": "WA", "execution_time": "1229 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Apply U gate once\n    qc.compose(U(), inplace=True)\n    \n    # Iteratively apply R(theta) gate with incremental phase shifts\n    for _ in range(100):\n        qc.compose(R(0.01), inplace=True)  # Small phase shift for iterative approach\n        qc.compose(U(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A6DEA4F1DEC2B", "submission_order": 2, "result": "DLE", "execution_time": "1400 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply U gate first to move the initial state\n    qc.compose(U(), inplace=True)\n    \n    # Apply the Grover-like iteration to refine the state towards |omega>\n    # Here we use a loop with the max allowed number of R applications, but this could be tuned\n    for _ in range(100):\n        qc.compose(R(0), inplace=True)  # Apply R(θ) with given θ\n        qc.compose(U().inverse(), inplace=True)  # Apply U inverse\n        qc.compose(R(0), inplace=True)  # Apply R(θ) again\n        qc.compose(U(), inplace=True)  # Apply U again\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A6DEA4F1DEC2B", "submission_order": 3, "result": "WA", "execution_time": "1078 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply U to create an initial superposition\n    qc.compose(U(), inplace=True)\n    \n    # Apply R(θ) once or a few times to refine the state\n    qc.compose(R(0), inplace=True)\n    \n    # Apply the inverse of U to bring the state closer to |ω>\n    qc.compose(U().inverse(), inplace=True)\n    \n    # Apply R(θ) again if needed (depending on the results of the first application)\n    qc.compose(R(0), inplace=True)\n    \n    # A final application of U to finalize the state preparation\n    qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A6DEA4F1DEC2B", "submission_order": 4, "result": "RE", "execution_time": "1045 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.05:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A6DEA4F1DEC2B", "submission_order": 5, "result": "AC", "execution_time": "3242 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef get_rs(n, theta):\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n    \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(0, n-1)), n-1)\n    \n    qc.x(range(n))\n\n    return qc\n\ndef compose(n, u, rs, rt):\n    qc = QuantumCircuit(n)\n\n    qc.compose(u, inplace=True)\n    qc.compose(rt, inplace=True)\n    qc.compose(u.inverse(), inplace=True)\n    qc.compose(rs, inplace=True)\n    qc.compose(u, inplace=True)\n\n    return qc\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    if P < 0.05:\n        u0 = QuantumCircuit(n)\n        u0.ry(1, range(n))\n        u0.h(range(n))\n    else:\n        u0 = U()\n\n    rs = get_rs(n, math.pi/3)\n    rt = R(math.pi/3)\n\n    u1 = compose(n, u0, rs, rt)\n    u2 = compose(n, u1, rs, rt)\n    u3 = compose(n, u2, rs, rt)\n    u4 = compose(n, u3, rs, rt)\n\n    return u4\n'''"}
{"problem": "QPC002_Ex", "user": "A7478C5998F3A", "submission_order": 1, "result": "AC", "execution_time": "2295 ms", "memory": "164 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\nfrom scipy.special import eval_chebyt\n \n \ndef R_0(n: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(range(n))\n \n    if n == 1:\n        qc.p(theta, 0)\n    else:\n        qc.mcp(theta, list(range(n - 1)), n - 1)\n \n    qc.x(range(n))\n \n    return qc\n \n \n# Calculate the minimum number of query L\ndef calculate_L(delta: float, lambda_: float) -> int:\n    L = int(math.ceil(math.log(2 / delta) / math.sqrt(lambda_)))\n \n    # Check if L is odd\n    if L % 2 == 0:\n        L += 1\n \n    return L\n \n \ndef calculate_gamma(L: int, delta: float) -> float:\n    # Calculate the Chebyshev polynomial T_{1/L}(1/δ)\n    chebyshev_value = eval_chebyt(1 / L, 1 / delta)\n \n    # γ is the inverse of the Chebyshev value\n    return 1 / chebyshev_value\n \n \n# Define the fixed-point Grover's algorithm\ndef fixed_point_grover(n: int, delta: float, lambda_: float, U, R) -> QuantumCircuit:\n    L = calculate_L(delta, lambda_)\n \n    # Calculate the angles for Grover's iteration\n    gamma = calculate_gamma(L, delta)\n    angles = [\n        -2 * math.atan(1 / (math.tan(2 * math.pi * j / L) * math.sqrt(1 - gamma**2)))\n        for j in range(1, L // 2 + 1)\n    ]\n \n    qc = QuantumCircuit(n)\n    qc.compose(U(), inplace=True)\n    for alpha, beta in zip(angles, reversed(angles)):\n        qc.compose(R(beta), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        qc.compose(R_0(n, alpha), inplace=True)\n        qc.compose(U(), inplace=True)\n \n    return qc\n \n \ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    delta = 0.01\n    lambda_ = P\n    return fixed_point_grover(n, delta, lambda_, U, R)\n'''"}
{"problem": "QPC002_Ex", "user": "A757A60300768", "submission_order": 1, "result": "WA", "execution_time": "2025 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply the gate U to the initial state |0>\n    qc.compose(U(), inplace=True)\n    \n    # Step 2: Determine the number of times to apply R(theta)\n    # We will apply R(theta) multiple times to converge to |omega>\n    # The number of applications can be adjusted based on P\n    num_R_applications = min(100, int(100 * (1 - P)))  # Example heuristic\n    \n    # Step 3: Apply R(theta) multiple times\n    theta = 0.1  # Example value for theta, can be adjusted\n    for _ in range(num_R_applications):\n        qc.compose(R(theta), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A757A60300768", "submission_order": 2, "result": "DLE", "execution_time": "1987 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Initialize the state |omega> using U and R gates\n    qc.compose(U(), inplace=True)\n    qc.compose(R(0), inplace=True)  # Initialize |omega> with R(0)\n    \n    # Apply R(theta) gate to prepare the state |omega>\n    for _ in range(100):\n        qc.compose(R(0.01), inplace=True)  # Apply R(0.01) gate iteratively\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A7E68578D8B33", "submission_order": 1, "result": "WA", "execution_time": "1607 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A7E68578D8B33", "submission_order": 2, "result": "RE", "execution_time": "2456 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    \n    \n    theta = np.arccos(np.sqrt(P)) \n    for _ in range(10): \n        qc.compose(R(theta), inplace=True)\n    \n    qc.compose(U().inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A7E68578D8B33", "submission_order": 3, "result": "WA", "execution_time": "1533 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    \n    \n    theta = np.arccos(np.sqrt(P)) \n    for _ in range(10): \n        qc.compose(R(theta), inplace=True)\n    \n    qc.compose(U().inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "A806716018B93", "submission_order": 1, "result": "RE", "execution_time": "1219 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(),inplace=True)\n    theta = np.arccos(np.sqrt(p))*2\n\n    m = int(np.pi/2/theta - 0.5)\n    for i in range(m):\n        qc.compose(R(np.pi), inplace=True)\n\n        qc.compose(U(),inplace=True)\n        qc.x(range(n))\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n        qc.x(range(n))\n        qc.compose(U(),inplace=True)\n\n        \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 1, "result": "WA", "execution_time": "1298 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Calculate the number of iterations\n    num_iterations = math.floor(math.pi / (4 * math.asin(math.sqrt(P))))\n    \n    # Apply U to prepare the initial superposition\n    qc.compose(U(), inplace=True)\n    \n    # Amplitude amplification\n    for _ in range(num_iterations):\n        # Apply R(pi) which is equivalent to the oracle\n        qc.compose(R(math.pi), inplace=True)\n        \n        # Apply U\n        qc.compose(U(), inplace=True)\n        \n        # Apply R(0) which is equivalent to the diffusion operator\n        qc.compose(R(0), inplace=True)\n        \n        # Apply U inverse\n        qc.compose(U().inverse(), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 2, "result": "WA", "execution_time": "1190 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply U to prepare the initial state\n    qc.compose(U(), inplace=True)\n    \n    # Calculate the phase for R\n    theta = 2 * math.asin(math.sqrt(P))\n    \n    # Apply phase estimation\n    num_iterations = int(math.pi / (2 * theta))\n    \n    for _ in range(num_iterations):\n        qc.compose(R(theta), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 3, "result": "WA", "execution_time": "1098 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Calculate the phase for R\n    theta = 2 * math.asin(math.sqrt(P))\n    \n    # Calculate the number of iterations\n    L = min(math.pi / (2 * theta), 100)  # Ensure we don't exceed 100 applications\n    m = math.ceil(math.log(L, 2))  # Number of bits for phase estimation\n    \n    # Apply U to prepare the initial state\n    qc.compose(U(), inplace=True)\n    \n    # Fixed-Point Quantum Search\n    for k in range(m):\n        # Apply controlled rotation\n        angle = 2 * math.pi / (2 ** (k + 1))\n        for j in range(2**k):\n            qc.compose(R(angle), inplace=True)\n        \n        # Apply U†\n        qc.compose(U().inverse(), inplace=True)\n        \n        # Apply controlled-Z\n        qc.z(0)\n        \n        # Apply U\n        qc.compose(U(), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 4, "result": "WA", "execution_time": "1449 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply U to prepare the initial state\n    qc.compose(U(), inplace=True)\n    \n    # Calculate the optimal number of iterations\n    m = math.floor(math.pi / (4 * math.asin(math.sqrt(P))) - 0.5)\n    m = min(m, 50)  # Ensure we don't exceed 100 applications of R\n    \n    # Apply amplitude amplification\n    for _ in range(m):\n        # Apply R(π)\n        qc.compose(R(math.pi), inplace=True)\n        \n        # Apply U†\n        qc.compose(U().inverse(), inplace=True)\n        \n        # Apply R(π)\n        qc.compose(R(math.pi), inplace=True)\n        \n        # Apply U\n        qc.compose(U(), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 5, "result": "WA", "execution_time": "1114 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"You can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\"\"\"\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    \n    # Apply U to prepare the initial state\n    qc.compose(U(), inplace=True)\n    \n    # Calculate the optimal number of iterations\n    m = math.floor(math.pi / (4 * math.asin(math.sqrt(P))) - 0.5)\n    m = min(m, 50)  # Ensure we don't exceed 100 applications of R\n    \n    # Apply amplitude amplification\n    for _ in range(m):\n        # Apply R(π)\n        qc.compose(R(math.pi), inplace=True)\n        \n        # Apply U†\n        qc.compose(U().inverse(), inplace=True)\n        \n        # Apply R(π)\n        qc.compose(R(math.pi), inplace=True)\n        \n        # Apply U\n        qc.compose(U(), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 6, "result": "WA", "execution_time": "1153 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"You can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\"\"\"\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n    \n    qc.compose(U(), inplace=True)\n    \n    m = min(int(math.pi / (4 * math.asin(math.sqrt(P))) - 0.5), 50)\n    \n    for _ in range(m):\n        qc.compose(R(math.pi), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        qc.compose(R(math.pi), inplace=True)\n        qc.compose(U(), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 7, "result": "WA", "execution_time": "1296 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"You can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\"\"\"\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n    \n    qc.compose(U(), inplace=True)\n    \n    theta = 2 * math.asin(math.sqrt(P))\n    iterations = min(int(math.pi / (2 * theta)), 100)\n    \n    for _ in range(iterations):\n        qc.compose(R(theta), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 8, "result": "WA", "execution_time": "1063 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"You can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\"\"\"\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n    \n    # Apply U to prepare the initial state\n    qc.compose(U(), inplace=True)\n    \n    # Calculate the number of iterations\n    m = min(int(1 / math.sqrt(P)), 100)\n    \n    # Apply phase estimation\n    for k in range(m):\n        theta = 2 * math.pi / (2 ** (k + 1))\n        qc.compose(R(theta), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 9, "result": "WA", "execution_time": "1080 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply U to the quantum circuit\n    qc.compose(U(), inplace=True)\n    \n    # Choose theta based on P\n    # Note: We need to derive or choose theta such that the projection yields the probability P.\n    # This is often done by solving equations or approximations, but for simplicity, \n    # we will use a fixed theta as an example. This will need adjustment based on P.\n    # We use a placeholder theta here; you need to compute this based on the problem requirements.\n    theta = np.arccos(np.sqrt(P))  # Example, adjust according to exact requirements\n    \n    # Apply R(theta) to the quantum circuit\n    qc.compose(R(theta), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 10, "result": "WA", "execution_time": "1117 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply U to the quantum circuit\n    qc.compose(U(), inplace=True)\n    \n    # Calculate theta based on P\n    # We solve for theta where:\n    # P = |⟨ω|U|0⟩|^2\n    # For simplicity, we'll use a direct calculation for theta\n    # which is typically derived from the problem specifics. Here, a generic example.\n    # Ensure the calculation matches the probability requirement.\n    \n    # Example: theta calculation\n    theta = 2 * np.arccos(np.sqrt(P))\n    \n    # Apply R(theta) to the quantum circuit\n    qc.compose(R(theta), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB25428AD0585", "submission_order": 11, "result": "WA", "execution_time": "1113 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply U to the quantum circuit\n    qc.compose(U(), inplace=True)\n    \n    # Compute theta\n    # We use P to determine theta for the R(theta) gate.\n    # Since theta needs to match the probability P, we use:\n    # theta = 2 * arccos(sqrt(P))\n    theta = 2 * np.arccos(np.sqrt(P))\n    \n    # Apply R(theta) to the quantum circuit\n    qc.compose(R(theta), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB50E4ED77BBC", "submission_order": 1, "result": "WA", "execution_time": "1154 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(100):\n    qc.compose(U(), inplace=True)\n    qc.compose(R(1), inplace=True)\n  return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB50E4ED77BBC", "submission_order": 2, "result": "WA", "execution_time": "1478 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n  qc = QuantumCircuit(n)\n  for i in range(50):\n    qc.compose(U(), inplace=True)\n    qc.compose(R(math.pi), inplace=True)\n    qc.compose(U().inverse(), inplace=True)\n    qc.compose(R(math.pi).inverse(), inplace=True)\n  return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB84161F073F6", "submission_order": 1, "result": "WA", "execution_time": "1082 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    from math import acos, sqrt, pi\n    theta = 2 * acos(sqrt(P))\n    \n    # Compute the inverse theta\n    qc.compose(R(theta).inverse(), inplace=True)\n    \n    # Apply U inverse\n    qc.compose(U().inverse(), inplace=True)\n\n    # Apply R(theta) again\n    qc.compose(R(theta), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AB84161F073F6", "submission_order": 2, "result": "WA", "execution_time": "1174 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    num_iterations = 10  # Adjust as needed\n\n    # Initial application of U\n    qc.compose(U(), inplace=True)\n\n    # Amplitude amplification loop\n    for _ in range(num_iterations):\n        qc.compose(R(np.pi/2), inplace=True)  # Assuming optimal theta\n        qc.compose(U().inverse(), inplace=True)\n        qc.compose(R(np.pi/2), inplace=True)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 1, "result": "RE", "execution_time": "1112 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range (100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 2, "result": "RE", "execution_time": "1143 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range (100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        #qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 3, "result": "RE", "execution_time": "1505 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range (100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 4, "result": "RE", "execution_time": "1288 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range (100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        #qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 5, "result": "WA", "execution_time": "1155 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    #for i in range(100):\n    #    qc.compose(R(math.pi / 3), inplace=True)\n    #    qc.compose(U().inverse(), inplace=True)\n    #    for j in range(n):\n    #        qc.x(j)\n    #    qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n    #    for j in range(n):\n    #        qc.x(j)\n    #    qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 6, "result": "RE", "execution_time": "1064 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range(100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(U().replace(operation=U().operation.inverse(annotated=annotated)), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 7, "result": "RE", "execution_time": "1232 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range(100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc2 = QuantumCircuit(n)\n        qc2.compose(U(), inplace=True)\n        qc.append(qc2.inverse(), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 8, "result": "RE", "execution_time": "1178 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range(100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(U(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 9, "result": "WA", "execution_time": "1220 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range(100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(U(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(math.pi / 3, 0)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 10, "result": "RE", "execution_time": "1335 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range(100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(inverse(U()), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(math.pi / 3, 0)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 11, "result": "RE", "execution_time": "1137 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range(100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(U.inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(math.pi / 3, 0)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 12, "result": "RE", "execution_time": "1266 ms", "memory": "139 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    for i in range(100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(inverse(U), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(math.pi / 3, 0)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 13, "result": "WA", "execution_time": "1404 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n\n    for i in range(100):\n        qc.compose(R(math.pi / 3), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(math.pi / 3, 0)\n        else:\n            qc.append(PhaseGate(math.pi / 3).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 14, "result": "RE", "execution_time": "1076 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    delta=0.1\n    L=int(np.log(1/delta)/np.sqrt(P)/2)*2 + 1\n    gamma = 1/(np.cos((1/L)*np.arccos(1/delta)))\n    l = (L-1)/2\n    alpha=[]\n    beta=[]\n    for i in range(l):\n        alpha.append(2*np.arctan(1/(np.tan(i*np.pi*2/L)*np.sqrt(1-gamma**2))))\n\n    for i in range(l):\n        qc.compose(R(alpha[l-i-1]), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(alpha[i], 0)\n        else:\n            qc.append(PhaseGate(alpha[i]).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 15, "result": "RE", "execution_time": "1089 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    delta=0.1\n    L=int(np.log(1/delta)/np.sqrt(P)/2)*2 + 1\n    gamma = 1/(np.cos((1/L)*np.arccos(1/delta)))\n    l = int(np.log(1/delta)/np.sqrt(P)/2)\n    alpha=[]\n    beta=[]\n    for i in range(l):\n        alpha.append(2*np.arctan(1/(np.tan(i*np.pi*2/L)*np.sqrt(1-gamma**2))))\n\n    for i in range(l):\n        qc.compose(R(alpha[l-i-1]), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(alpha[i], 0)\n        else:\n            qc.append(PhaseGate(alpha[i]).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 16, "result": "RE", "execution_time": "1148 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    delta=0.1\n    L=int(np.log(1/delta)/np.sqrt(P)/2)*2 + 1\n    gamma = 1/(np.cos((1/L)*np.arccos(1/delta)))\n    l = int(np.log(1/delta)/np.sqrt(P)/2)\n    alpha=[]\n    for i in range(l):\n        alpha.append(2*np.arctan(1/(np.tan(i*np.pi*2/L)*np.sqrt(1-gamma**2))))\n\n    for i in range(l):\n        qc.compose(R(-alpha[l-i-1]), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(alpha[i], 0)\n        else:\n            qc.append(PhaseGate(-alpha[i]).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 17, "result": "RE", "execution_time": "1158 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    delta=0.1\n    L=int(np.log(2/delta)/np.sqrt(P)/2)*2 + 1\n    gamma = 1/(1-(np.log(1/delta)/L)**2)\n    l = int(np.log(2/delta)/np.sqrt(P)/2)\n    alpha=[]\n    for i in range(l):\n        alpha.append(2*np.arctan(1/(np.tan(i*np.pi*2/L)*np.sqrt(1-gamma**2))))\n\n    for i in range(l):\n        qc.compose(R(-alpha[l-i-1]), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(alpha[i], 0)\n        else:\n            qc.append(PhaseGate(-alpha[i]).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 18, "result": "WA", "execution_time": "1495 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    delta=0.1\n    L=int(np.log(2/delta)/np.sqrt(P)/2)*2 + 1\n    gamma = 1/(1-(np.log(1/delta)/L)**2)\n    l = int(np.log(2/delta)/np.sqrt(P)/2)\n    alpha=[]\n    for i in range(l):\n        #alpha.append(2*np.arctan(1/(np.tan(i*np.pi*2/L)*np.sqrt(1-gamma**2))))\n        alpha.append(np.pi/3)\n\n    for i in range(l):\n        qc.compose(R(-alpha[l-i-1]), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(alpha[i], 0)\n        else:\n            qc.append(PhaseGate(-alpha[i]).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 19, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    delta=0.1\n    L=int(np.log(2/delta)/np.sqrt(P)/2)*2 + 1\n    gamma = 1/(1-(np.log(1/delta)/L)**2)\n    l = int(np.log(2/delta)/np.sqrt(P)/2)\n    alpha=[]\n    for i in range(100):\n        #alpha.append(2*np.arctan(1/(np.tan(i*np.pi*2/L)*np.sqrt(1-gamma**2))))\n        alpha.append(np.pi/)\n\n    for i in range(100):\n        qc.compose(R(-alpha[l-i-1]), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(alpha[i], 0)\n        else:\n            qc.append(PhaseGate(-alpha[i]).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 20, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    delta=0.1\n    L=int(np.log(2/delta)/np.sqrt(P)/2)*2 + 1\n    gamma = 1/(1-(np.log(1/delta)/L)**2)\n    l = int(np.log(2/delta)/np.sqrt(P)/2)\n    alpha=[]\n    for i in range(100):\n        #alpha.append(2*np.arctan(1/(np.tan(i*np.pi*2/L)*np.sqrt(1-gamma**2))))\n        alpha.append(np.pi/)\n\n    for i in range(100):\n        qc.compose(R(-alpha[100-i-1]), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(alpha[i], 0)\n        else:\n            qc.append(PhaseGate(-alpha[i]).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD2410AE1BCC8", "submission_order": 21, "result": "WA", "execution_time": "1186 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    delta=0.1\n    L=int(np.log(2/delta)/np.sqrt(P)/2)*2 + 1\n    gamma = 1/(1-(np.log(1/delta)/L)**2)\n    l = int(np.log(2/delta)/np.sqrt(P)/2)\n    alpha=[]\n    for i in range(100):\n        #alpha.append(2*np.arctan(1/(np.tan(i*np.pi*2/L)*np.sqrt(1-gamma**2))))\n        alpha.append(np.pi/3)\n\n    for i in range(100):\n        qc.compose(R(-alpha[100-i-1]), inplace=True)\n        qc.compose(U().inverse(), inplace=True)\n        for j in range(n):\n            qc.x(j)\n        if(n==1):\n            qc.p(alpha[i], 0)\n        else:\n            qc.append(PhaseGate(-alpha[i]).control(n - 1), range(n))\n        for j in range(n):\n            qc.x(j)\n        qc.compose(U(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD800E4494D52", "submission_order": 1, "result": "RE", "execution_time": "1042 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(U, range(n))\n    \n    # Define the phase gate R(θ) in terms of RZ and I\n    # Note: This example assumes R(θ) has a known structure. You might need to adapt it to your specific case.\n    def R(theta):\n        # R(theta) = I - (1 - e^iθ) |ω⟩⟨ω|\n        # Assume ω is the state after applying U\n        # In the ideal case, we would need to apply RZ or other gates based on θ\n        qc.rz(theta, 0)  # Example phase gate\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD800E4494D52", "submission_order": 2, "result": "RE", "execution_time": "1291 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(U, range(n))\n    def R(theta):\n        qc.rz(theta, 0)  \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD800E4494D52", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(U, range(n))\n    \n    # Define the phase gate R(θ) in terms of RZ and I\n    # Note: This example assumes R(θ) has a known structure. You might need to adapt it to your specific case.\n    def R(theta):\n         R(theta) = I - (1 - e^iθ) |ω⟩⟨ω|\n        # Assume ω is the state after applying U\n        # In the ideal case, we would need to apply RZ or other gates based on θ\n        qc.rz(theta, 0)  # Example phase gate\n        return qc\n    \n    # Apply R(θ) to the circuit\n    qc = R(theta)  \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD800E4494D52", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(U, range(n))\n    def R(theta):\n         R(theta) = I - (1 - e^iθ) |ω⟩⟨ω|\n    qc = R(theta)  \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD800E4494D52", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(U, range(n))\n    def R(theta):\n         R(theta) = I - (1 - e^i(theta)) |ω⟩⟨ω|\n    qc = R(theta)  \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AD800E4494D52", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(U, range(n))\n    \n    def R(theta):\n         R(theta) = I - (1 - e^i(theta)) |ω⟩⟨ω|\n    qc.append(R(theta), range(n))\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AF774607990AF", "submission_order": 1, "result": "WA", "execution_time": "1833 ms", "memory": "161 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Step 1: Prepare initial state using U\n    qc.compose(U(), inplace=True)\n    \n    # If initial probability is already high enough, return the circuit as is\n    if P >= 0.99:\n        return qc\n    \n    # Step 2: Calculate the initial angle and determine rotation counts\n    theta0 = math.asin(math.sqrt(P))             # initial angle such that sin^2(theta0) = P\n    # Determine the number of full rotations without overshooting π/2\n    if theta0 == 0: \n        k_full = 0\n    else:\n        k_full = math.floor((math.pi/2 - theta0) / (2 * theta0))\n    # Compute the angle achieved after k_full full rotations\n    achieved_angle = (2 * k_full + 1) * theta0\n    # Compute the partial rotation needed to reach π/2 (optimal) from achieved_angle\n    theta_partial = (math.pi/2) - achieved_angle\n    \n    # Step 3: Apply k_full full R rotations\n    full_rotation_angle = 2 * theta0  # angle for one full Grover iteration\n    for _ in range(k_full):\n        qc.compose(R(full_rotation_angle), inplace=True)\n    \n    # Step 4: Apply a partial rotation if needed to reach >= 99% success\n    if theta_partial > 1e-6:  # if a significant partial rotation remains\n        qc.compose(R(2 * theta_partial), inplace=True)\n        # Note: If R(θ) is defined to perform a rotation by θ directly, \n        # we should use R(theta_partial) here instead of R(2*theta_partial).\n        # The factor 2 accounts for the typical Grover double-angle per iteration.\n    \n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AF774607990AF", "submission_order": 2, "result": "WA", "execution_time": "1777 ms", "memory": "163 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # 初期状態の準備: U を適用\n    qc.compose(U(), inplace=True)\n\n    # 初期成功確率 P のアークサインを計算\n    theta0 = math.asin(math.sqrt(P))\n\n    # 固定点量子探索 (Grover-Yoder) の適用回数を決定\n    k_max = min(100, math.ceil(math.log(1 / (1 - 0.99)) / math.log(3)))  # 保守的に100以下に制限\n\n    # Grover-Yoder 法の位相シフトを適用\n    for k in range(1, k_max + 1):\n        theta_k = math.pi / (2 * k + 2)  # 位相シフト\n        qc.compose(R(2 * theta_k), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AF774607990AF", "submission_order": 3, "result": "WA", "execution_time": "1740 ms", "memory": "163 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # 初期状態の準備: U を適用\n    qc.compose(U(), inplace=True)\n\n    # 初期角度 theta_0 の計算\n    theta_k = math.asin(math.sqrt(P))\n\n    # FPQS の適用回数の決定 (最大 100 ステップ)\n    k_max = min(100, math.ceil(math.log(1 / (1 - 0.99)) / math.log(3)))  \n\n    for k in range(1, k_max + 1):\n        # Grover-Yoder の適切な角度更新\n        theta_k = math.atan( math.sin(theta_k) / (math.cos(theta_k) + 1 / math.tan(theta_k)) )\n\n        # 量子回路に FPQS ステップを適用\n        qc.compose(R(2 * theta_k), inplace=True)  # ターゲット状態の位相回転\n        qc.compose(U().inverse(), inplace=True)   # 逆変換\n        qc.compose(R(-2 * theta_k), inplace=True) # 逆位相回転\n        qc.compose(U(), inplace=True)             # もう一度 U を適用\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AF774607990AF", "submission_order": 4, "result": "DLE", "execution_time": "1759 ms", "memory": "164 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # 初期状態の準備: U を適用\n    qc.compose(U(), inplace=True)\n\n    # 初期角度 theta_0 の計算\n    theta_k = math.asin(math.sqrt(P))\n\n    # 固定点量子探索の最大反復回数\n    max_iterations = 100\n\n    for k in range(max_iterations):\n        # 現在の角度 theta_k に基づいて R(2 * theta_k) を適用\n        qc.compose(R(2 * theta_k), inplace=True)\n        # U の逆ゲートを適用\n        qc.compose(U().inverse(), inplace=True)\n        # R(-2 * theta_k) を適用\n        qc.compose(R(-2 * theta_k), inplace=True)\n        # U を再度適用\n        qc.compose(U(), inplace=True)\n\n        # 次の角度 theta_{k+1} を計算\n        theta_k = 2 * math.asin(math.sin(theta_k / 2))\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AF774607990AF", "submission_order": 5, "result": "WA", "execution_time": "1711 ms", "memory": "170 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # 初期状態の準備: U を適用\n    qc.compose(U(), inplace=True)\n\n    # 初期角度 theta_0 の計算\n    theta_k = math.asin(math.sqrt(P))\n\n    # 固定点量子探索の最大反復回数\n    max_iterations = 30\n\n    for k in range(max_iterations):\n        # 現在の角度 theta_k に基づいて R(2 * theta_k) を適用\n        qc.compose(R(2 * theta_k), inplace=True)\n        # U の逆ゲートを適用\n        qc.compose(U().inverse(), inplace=True)\n        # R(-2 * theta_k) を適用\n        qc.compose(R(-2 * theta_k), inplace=True)\n        # U を再度適用\n        qc.compose(U(), inplace=True)\n\n        # 次の角度 theta_{k+1} を計算\n        theta_k = 2 * math.asin(math.sin(theta_k / 2))\n\n    return qc\n'''"}
{"problem": "QPC002_Ex", "user": "AFC53E7F80E76", "submission_order": 1, "result": "RE", "execution_time": "1124 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply U and R as follows:\nqc.compose(U(), inplace=True)\nqc.compose(R(theta), inplace=True)\n\"\"\"\n\n\ndef solve(n: int, P: float, U, R) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(U(), inplace=True)\n    qc.compose(R(theta), inplace=True)\n    qc.compose(U().inverse(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A011ED81C9F48", "submission_order": 1, "result": "WA", "execution_time": "1569 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A011ED81C9F48", "submission_order": 2, "result": "AC", "execution_time": "1255 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A01AFC86A4766", "submission_order": 1, "result": "AC", "execution_time": "1573 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A01F89409E98D", "submission_order": 1, "result": "AC", "execution_time": "1527 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A029A3E381B53", "submission_order": 1, "result": "WA", "execution_time": "1592 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.global_phase += math.pi/2\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A029A3E381B53", "submission_order": 2, "result": "AC", "execution_time": "1854 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A037524E62E17", "submission_order": 1, "result": "AC", "execution_time": "1212 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A04F7C0AE2627", "submission_order": 1, "result": "AC", "execution_time": "1220 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A06EC03617CA7", "submission_order": 1, "result": "WA", "execution_time": "1506 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.z(0)\n    qc.y(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A06EC03617CA7", "submission_order": 2, "result": "AC", "execution_time": "1264 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0A2AB4BD4B48", "submission_order": 1, "result": "WA", "execution_time": "1567 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.rz(math.pi, 0)\n    qc.ry(math.pi, 0)\n \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0A2AB4BD4B48", "submission_order": 2, "result": "AC", "execution_time": "1580 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.rz(-math.pi, 0)\n    qc.ry(math.pi, 0)\n \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0ABC0A4A09DD", "submission_order": 1, "result": "AC", "execution_time": "1256 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0D00F2A0C1D4", "submission_order": 1, "result": "RE", "execution_time": "1698 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.Y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0D00F2A0C1D4", "submission_order": 2, "result": "AC", "execution_time": "1661 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0D7E0DD6DFAF", "submission_order": 1, "result": "AC", "execution_time": "1226 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0DDC804B8384", "submission_order": 1, "result": "AC", "execution_time": "1790 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0E43A6122C67", "submission_order": 1, "result": "AC", "execution_time": "1488 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0E8C62419D95", "submission_order": 1, "result": "WA", "execution_time": "1453 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi / 2))\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0E8C62419D95", "submission_order": 2, "result": "AC", "execution_time": "1381 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi / 2))\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0EFCA4174B5F", "submission_order": 1, "result": "AC", "execution_time": "1255 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import YGate\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.append(YGate(), [0])\n \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0F8630251A90", "submission_order": 1, "result": "WA", "execution_time": "1853 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.p(math.pi / 2, -0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A0F8630251A90", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(math.pi/2, 0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A1", "user": "A0F8630251A90", "submission_order": 3, "result": "WA", "execution_time": "1733 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(math.pi/2, 0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A1", "user": "A0F8630251A90", "submission_order": 4, "result": "AC", "execution_time": "1462 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(math.pi/2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A1087AEC2AD49", "submission_order": 1, "result": "AC", "execution_time": "2025 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the S gate to the |1> state\n    qc.x(0)  # First, we need to flip |0> to |1>\n    qc.s(0)  # Apply the S gate to introduce the phase\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A112DD1F6DB8F", "submission_order": 1, "result": "WA", "execution_time": "1433 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A112DD1F6DB8F", "submission_order": 2, "result": "WA", "execution_time": "1715 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)#at 0\n    qc.h(0)#|->\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A130FAB8DADD3", "submission_order": 1, "result": "WA", "execution_time": "1363 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A149D8D76EBD5", "submission_order": 1, "result": "AC", "execution_time": "1544 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A170D9AB43336", "submission_order": 1, "result": "AC", "execution_time": "1856 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(3*pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A204EFF5CD74D", "submission_order": 1, "result": "AC", "execution_time": "1694 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A23416D952662", "submission_order": 1, "result": "AC", "execution_time": "1686 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A235814DF1E73", "submission_order": 1, "result": "AC", "execution_time": "1545 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2443080AB6F4", "submission_order": 1, "result": "AC", "execution_time": "1436 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A244E4D0A2D6C", "submission_order": 1, "result": "AC", "execution_time": "2132 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A26ECC55D1A1E", "submission_order": 1, "result": "AC", "execution_time": "1413 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    theta = math.pi/2\n    qc.x(0)\n    qc.p(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2A393E8FAD11", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom glskit import QuantumCircuit  \n\ndef solve() -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  \n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2A393E8FAD11", "submission_order": 2, "result": "AC", "execution_time": "1519 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  \n\ndef solve() -> QuantumCircuit:  \n    qc = QuantumCircuit(1)  \n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2B4BC8F1C66E", "submission_order": 1, "result": "WA", "execution_time": "1198 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2B4BC8F1C66E", "submission_order": 2, "result": "AC", "execution_time": "1636 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2B837AC1A3C2", "submission_order": 1, "result": "WA", "execution_time": "1635 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2B837AC1A3C2", "submission_order": 2, "result": "WA", "execution_time": "1240 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(0)\n    qc.h(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2B837AC1A3C2", "submission_order": 3, "result": "AC", "execution_time": "1216 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A2D14318B0071", "submission_order": 1, "result": "AC", "execution_time": "1196 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A36D92A49C192", "submission_order": 1, "result": "AC", "execution_time": "1597 ms", "memory": "155 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A386DDF77988B", "submission_order": 1, "result": "AC", "execution_time": "1586 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n    return qc\n\nif __name__ == '__main__':\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A1", "user": "A38D3413436E5", "submission_order": 1, "result": "RE", "execution_time": "1630 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(np.pi/2)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A38D3413436E5", "submission_order": 2, "result": "RE", "execution_time": "1510 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(np.pi/2)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A38D3413436E5", "submission_order": 3, "result": "RE", "execution_time": "1565 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(np.pi/2)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A38D3413436E5", "submission_order": 4, "result": "AC", "execution_time": "1264 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A3FEAC1B1D96F", "submission_order": 1, "result": "WA", "execution_time": "1893 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A3FEAC1B1D96F", "submission_order": 2, "result": "AC", "execution_time": "2048 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A41145DCECFFC", "submission_order": 1, "result": "AC", "execution_time": "1294 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A4446F856C52A", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library import ZGate\nfrom math import sqrt, acos, pi\n\ndef solve():\n\tqc = QuantumCircuit(1)\n\tqc.y(0)\n\treturn qc\n'''"}
{"problem": "QPC003_A1", "user": "A4446F856C52A", "submission_order": 2, "result": "AC", "execution_time": "1605 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom math import sqrt, acos, pi\n\ndef solve():\n\tqc = QuantumCircuit(1)\n\tqc.y(0)\n\treturn qc\n'''"}
{"problem": "QPC003_A1", "user": "A475F77E8C273", "submission_order": 1, "result": "RE", "execution_time": "1705 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A475F77E8C273", "submission_order": 2, "result": "AC", "execution_time": "1754 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A479631D93240", "submission_order": 1, "result": "RE", "execution_time": "1153 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.p(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A479631D93240", "submission_order": 2, "result": "WA", "execution_time": "1705 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A479631D93240", "submission_order": 3, "result": "AC", "execution_time": "1428 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A47A63432E89A", "submission_order": 1, "result": "AC", "execution_time": "1684 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A480C1CDBBE2E", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    import maath\n    qc.x(0)\n    qc.p(math.pi/2,0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A480C1CDBBE2E", "submission_order": 2, "result": "AC", "execution_time": "1534 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    import math\n    qc.x(0)\n    qc.p(math.pi/2,0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A48C8A682F875", "submission_order": 1, "result": "WA", "execution_time": "1516 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A48C8A682F875", "submission_order": 2, "result": "RE", "execution_time": "1335 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.rx(math.PI)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A48C8A682F875", "submission_order": 3, "result": "RE", "execution_time": "1393 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.rx(math.PI*-1)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A48C8A682F875", "submission_order": 4, "result": "AC", "execution_time": "1504 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    #qc.rx(math.PI*-1)\n    qc.x(0)\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A4A9A8F167467", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n     qc.x(0)\n    qc.s(0) \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A4BA018FAE471", "submission_order": 1, "result": "WA", "execution_time": "1482 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A4BA018FAE471", "submission_order": 2, "result": "WA", "execution_time": "1654 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.s(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A4BA018FAE471", "submission_order": 3, "result": "AC", "execution_time": "1439 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A4E7038DA981A", "submission_order": 1, "result": "AC", "execution_time": "1244 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A4F35FFCEFC15", "submission_order": 1, "result": "AC", "execution_time": "1600 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A4F978EC82373", "submission_order": 1, "result": "AC", "execution_time": "1544 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A520CC9695CD4", "submission_order": 1, "result": "WA", "execution_time": "1595 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A520CC9695CD4", "submission_order": 2, "result": "AC", "execution_time": "1454 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A524B98DB9684", "submission_order": 1, "result": "AC", "execution_time": "1601 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(math.pi / 2, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A55559D59B639", "submission_order": 1, "result": "WA", "execution_time": "1715 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n    qc.x(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2, 3, [1, 3])\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     # sv = Statevector.from_label('01000')\n#     # print(sv.evolve(qc))\n'''"}
{"problem": "QPC003_A1", "user": "A55559D59B639", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n    return qc\n\nif __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    import numpy as np\n    qc = solve()\n    sv = Statevector(qc)\n    print(sv)\n    print(qc)\n    print(f\"{qc.depth() = }\")\n    # sv = Statevector.from_label('01000')\n    # print(sv.evolve(qc))\n'''"}
{"problem": "QPC003_A1", "user": "A55559D59B639", "submission_order": 3, "result": "AC", "execution_time": "1848 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A56AE6FFD014D", "submission_order": 1, "result": "WA", "execution_time": "1555 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A56AE6FFD014D", "submission_order": 2, "result": "AC", "execution_time": "1620 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A589FA503324C", "submission_order": 1, "result": "AC", "execution_time": "1532 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A5B7458CE5389", "submission_order": 1, "result": "AC", "execution_time": "1602 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A5B775BF8A92C", "submission_order": 1, "result": "AC", "execution_time": "1940 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\n\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(1)\n\n  qc.x(0)\n  qc.s(0)\n\n\n  return qc\n'''"}
{"problem": "QPC003_A1", "user": "A5C66DB9D9621", "submission_order": 1, "result": "RE", "execution_time": "1465 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A5C66DB9D9621", "submission_order": 2, "result": "AC", "execution_time": "1493 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A5CDAB3A3F4AD", "submission_order": 1, "result": "WA", "execution_time": "1333 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A5CDAB3A3F4AD", "submission_order": 2, "result": "AC", "execution_time": "1312 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A6060EEEFEED9", "submission_order": 1, "result": "AC", "execution_time": "1548 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A60F146B280A5", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A628D4B93F20D", "submission_order": 1, "result": "AC", "execution_time": "1474 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A641DFDEC47C1", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom quskit import QuantumCircuit\nqc= QuantumCircuit(1)\nqc.x(0)\n\nqc.draw('mpl')\n'''"}
{"problem": "QPC003_A1", "user": "A641DFDEC47C1", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom quskit import QuantumCircuit\nqc= QuantumCircuit(1)\nqc.x(0)\n'''"}
{"problem": "QPC003_A1", "user": "A64E4329EB73B", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumRegister, ClassicalRegister, QuantumCircuit\nfrom numpy import pi\n\nqreg_q = QuantumRegister(1, 'q')\ncreg_c = ClassicalRegister(4, 'c')\ncircuit = QuantumCircuit(qreg_q, creg_c)\n\ncircuit.x(qreg_q[0])\n'''"}
{"problem": "QPC003_A1", "user": "A64E4329EB73B", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumRegister, ClassicalRegister, QuantumCircuit\nfrom numpy import pi\n\nqreg_q = QuantumRegister(1, 'q')\ncreg_c = ClassicalRegister(4, 'c')\ncircuit = QuantumCircuit(qreg_q, creg_c)\n\ncircuit.x(qreg_q[0])\n'''"}
{"problem": "QPC003_A1", "user": "A64E4329EB73B", "submission_order": 3, "result": "AC", "execution_time": "1906 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A6857C34B75B3", "submission_order": 1, "result": "AC", "execution_time": "1382 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A685D0B22EE16", "submission_order": 1, "result": "AC", "execution_time": "1637 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.p(math.pi / 2, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A6A40BB912CA4", "submission_order": 1, "result": "AC", "execution_time": "1970 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi/2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A6B993DFAB077", "submission_order": 1, "result": "RE", "execution_time": "1535 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(GlobalPhaseGate(math.pi/2))\n    qc.x(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A1", "user": "A6B993DFAB077", "submission_order": 2, "result": "AC", "execution_time": "1244 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(GlobalPhaseGate(math.pi/2))\n    qc.x(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A1", "user": "A6D780DCEED36", "submission_order": 1, "result": "AC", "execution_time": "1207 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.s(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A70950E3A6BC5", "submission_order": 1, "result": "RE", "execution_time": "1479 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    qc.data\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7334FBE7BC07", "submission_order": 1, "result": "WA", "execution_time": "1774 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7334FBE7BC07", "submission_order": 2, "result": "AC", "execution_time": "1660 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A74EACBA4684D", "submission_order": 1, "result": "WA", "execution_time": "1198 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi/2,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A74EACBA4684D", "submission_order": 2, "result": "AC", "execution_time": "1468 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi/2,0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A776701D895DB", "submission_order": 1, "result": "WA", "execution_time": "1482 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7769A18B0139", "submission_order": 1, "result": "RE", "execution_time": "1744 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(1)\n    qc.y(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7769A18B0139", "submission_order": 2, "result": "AC", "execution_time": "1677 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A77B4EB6525EA", "submission_order": 1, "result": "WA", "execution_time": "1526 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A77B4EB6525EA", "submission_order": 2, "result": "WA", "execution_time": "1506 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A77B4EB6525EA", "submission_order": 3, "result": "AC", "execution_time": "1401 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A78996D676835", "submission_order": 1, "result": "AC", "execution_time": "1535 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(math.pi, 0)\n    qc.ry(math.pi, 0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A78BFAB9C2A04", "submission_order": 1, "result": "WA", "execution_time": "1261 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A78BFAB9C2A04", "submission_order": 2, "result": "AC", "execution_time": "1541 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7C8550CF5ED3", "submission_order": 1, "result": "RE", "execution_time": "1190 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.X(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7C8550CF5ED3", "submission_order": 2, "result": "WA", "execution_time": "1247 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7C8550CF5ED3", "submission_order": 3, "result": "RE", "execution_time": "1198 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7C8550CF5ED3", "submission_order": 4, "result": "WA", "execution_time": "1522 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7C8550CF5ED3", "submission_order": 5, "result": "AC", "execution_time": "1462 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A7E6B672267ED", "submission_order": 1, "result": "AC", "execution_time": "1229 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A848DE27D5F71", "submission_order": 1, "result": "AC", "execution_time": "1208 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\nqc.X(1)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\nqc.g(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 3, "result": "RE", "execution_time": "1620 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 4, "result": "WA", "execution_time": "1269 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 5, "result": "RE", "execution_time": "1459 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 6, "result": "RE", "execution_time": "1502 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    # Write your code here:\n    qc.g(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 7, "result": "RE", "execution_time": "1205 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    # Write your code here:\n    qc.x(0)\n    qc.g(1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 8, "result": "RE", "execution_time": "1665 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 9, "result": "RE", "execution_time": "1215 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.t(1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 10, "result": "RE", "execution_time": "1465 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n    qc.y(1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 11, "result": "RE", "execution_time": "1352 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(1)\n    qc.x(1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 12, "result": "WA", "execution_time": "1503 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 13, "result": "WA", "execution_time": "1405 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 14, "result": "RE", "execution_time": "1367 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(1)\n    qc.z(1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 15, "result": "WA", "execution_time": "1401 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(0)\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 16, "result": "WA", "execution_time": "1762 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(0)\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 17, "result": "WA", "execution_time": "1495 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 18, "result": "RE", "execution_time": "1410 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 19, "result": "RE", "execution_time": "1458 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 20, "result": "RE", "execution_time": "1618 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 21, "result": "WA", "execution_time": "1605 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 22, "result": "WA", "execution_time": "1613 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(0)\n    qc.z(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A84A946DBBAA3", "submission_order": 23, "result": "WA", "execution_time": "1528 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.y(0)\n    qc.z(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A85820F78A832", "submission_order": 1, "result": "AC", "execution_time": "1916 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A8780DB54E79F", "submission_order": 1, "result": "AC", "execution_time": "1638 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A89CEFF3E1D18", "submission_order": 1, "result": "AC", "execution_time": "1439 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)  \n    qc.s(0)  \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A8BE4951B0001", "submission_order": 1, "result": "AC", "execution_time": "1245 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A8EDE958186DA", "submission_order": 1, "result": "WA", "execution_time": "1514 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A8EDE958186DA", "submission_order": 2, "result": "AC", "execution_time": "1426 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.s(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A8F452265225D", "submission_order": 1, "result": "AC", "execution_time": "1118 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    # 1量子ビットの回路を作成\n    qc = QuantumCircuit(1)\n    \n    # 初期状態 |0⟩ を |1⟩ にする\n    qc.x(0)\n    \n    # 状態に i を付与する (Sゲート)\n    qc.s(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A8FC5B3244A52", "submission_order": 1, "result": "AC", "execution_time": "1232 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A92778A38467A", "submission_order": 1, "result": "AC", "execution_time": "1268 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A92DD232F0E5D", "submission_order": 1, "result": "WA", "execution_time": "1719 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A92DD232F0E5D", "submission_order": 2, "result": "AC", "execution_time": "1475 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # qc.x(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A94CF0B08FA71", "submission_order": 1, "result": "WA", "execution_time": "1554 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A94CF0B08FA71", "submission_order": 2, "result": "AC", "execution_time": "1841 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9577948775F1", "submission_order": 1, "result": "WA", "execution_time": "1286 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9577948775F1", "submission_order": 2, "result": "AC", "execution_time": "1695 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(pi, 0)\n \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A1", "user": "A9678BAF10251", "submission_order": 1, "result": "AC", "execution_time": "2028 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A96B791620F86", "submission_order": 1, "result": "AC", "execution_time": "1547 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n#from qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A1", "user": "A97781C3F8260", "submission_order": 1, "result": "AC", "execution_time": "1565 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # |0⟩から|1⟩に遷移させ、iの位相を加える\n    qc.x(0)  # |0⟩を|1⟩にする\n    qc.p(3.14159/2, 0)  # |1⟩にiの位相を加える\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9793E6583F67", "submission_order": 1, "result": "WA", "execution_time": "1497 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(np.pi/2, 0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9793E6583F67", "submission_order": 2, "result": "AC", "execution_time": "1211 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rz(-np.pi/2, 0)\n    qc.x(0)\n    qc.rz(np.pi/2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A98B618682EB7", "submission_order": 1, "result": "AC", "execution_time": "1202 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9C1EC42CC44E", "submission_order": 1, "result": "AC", "execution_time": "1397 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9C77F4E394A3", "submission_order": 1, "result": "WA", "execution_time": "1269 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9C77F4E394A3", "submission_order": 2, "result": "AC", "execution_time": "1543 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9E3413648401", "submission_order": 1, "result": "RE", "execution_time": "1823 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.ry(pi/2)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9E3413648401", "submission_order": 2, "result": "WA", "execution_time": "1800 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.ry(pi/2,0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "A9E3413648401", "submission_order": 3, "result": "AC", "execution_time": "1835 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi/2,0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA081175209DD", "submission_order": 1, "result": "RE", "execution_time": "1173 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(i)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA081175209DD", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA081175209DD", "submission_order": 3, "result": "RE", "execution_time": "1284 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(i)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA081175209DD", "submission_order": 4, "result": "AC", "execution_time": "1324 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA103CAD5953F", "submission_order": 1, "result": "WA", "execution_time": "1453 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi/2, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA103CAD5953F", "submission_order": 2, "result": "WA", "execution_time": "1499 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi/2, 0)\n    qc.x(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA103CAD5953F", "submission_order": 3, "result": "AC", "execution_time": "1234 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.p(pi/2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA40C5DD0459F", "submission_order": 1, "result": "AC", "execution_time": "1467 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA5A0E35DE468", "submission_order": 1, "result": "RE", "execution_time": "1460 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA5A0E35DE468", "submission_order": 2, "result": "RE", "execution_time": "1814 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA5A0E35DE468", "submission_order": 3, "result": "RE", "execution_time": "1855 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA5A0E35DE468", "submission_order": 4, "result": "WA", "execution_time": "1793 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA5A0E35DE468", "submission_order": 5, "result": "RE", "execution_time": "1383 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA5A0E35DE468", "submission_order": 6, "result": "WA", "execution_time": "1245 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA5A0E35DE468", "submission_order": 7, "result": "AC", "execution_time": "1240 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AA75F15B466A6", "submission_order": 1, "result": "AC", "execution_time": "1238 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AAB7E787D34BA", "submission_order": 1, "result": "WA", "execution_time": "1762 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AAB7E787D34BA", "submission_order": 2, "result": "WA", "execution_time": "1700 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AAF86CC3E1432", "submission_order": 1, "result": "AC", "execution_time": "1491 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AB6E487E793E6", "submission_order": 1, "result": "AC", "execution_time": "1467 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AB867A072500F", "submission_order": 1, "result": "AC", "execution_time": "1495 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.s(0)\n \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ABA26CEA4BAA9", "submission_order": 1, "result": "AC", "execution_time": "1384 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ABC7B6967FDDD", "submission_order": 1, "result": "AC", "execution_time": "1509 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ABCED29489E8C", "submission_order": 1, "result": "AC", "execution_time": "1259 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ABEFD9C6E7506", "submission_order": 1, "result": "AC", "execution_time": "1299 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ABFA2D3066B59", "submission_order": 1, "result": "AC", "execution_time": "1898 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC0A46CBC994F", "submission_order": 1, "result": "WA", "execution_time": "1307 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC0A46CBC994F", "submission_order": 2, "result": "AC", "execution_time": "1312 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.s(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC18B271A0833", "submission_order": 1, "result": "WA", "execution_time": "1555 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.rz(pi / 2, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC18B271A0833", "submission_order": 2, "result": "AC", "execution_time": "1441 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.rz(pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC5565E5AE2D8", "submission_order": 1, "result": "AC", "execution_time": "1463 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC5DD5A9DCECD", "submission_order": 1, "result": "AC", "execution_time": "1513 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.sdg(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC65C011646E0", "submission_order": 1, "result": "AC", "execution_time": "1782 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC9785777CEB5", "submission_order": 1, "result": "WA", "execution_time": "1521 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC9785777CEB5", "submission_order": 2, "result": "RE", "execution_time": "1161 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.append(GlobalPhaseGate(pi/2))\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC9785777CEB5", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import GlobalPhaseGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.append(GlobalPhaseGate(pi/))\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AC9785777CEB5", "submission_order": 4, "result": "AC", "execution_time": "2058 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import GlobalPhaseGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.append(GlobalPhaseGate(pi/2))\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACB595DC292E6", "submission_order": 1, "result": "WA", "execution_time": "1312 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACB595DC292E6", "submission_order": 2, "result": "WA", "execution_time": "1261 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    qc.x(0\n    )\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACB595DC292E6", "submission_order": 3, "result": "AC", "execution_time": "1260 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n \n    qc.y(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACBB82557F904", "submission_order": 1, "result": "WA", "execution_time": "1652 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACBB82557F904", "submission_order": 2, "result": "WA", "execution_time": "1205 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    qc.y(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACBB82557F904", "submission_order": 3, "result": "WA", "execution_time": "1458 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACBB82557F904", "submission_order": 4, "result": "AC", "execution_time": "1490 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACDAA53FA3A8D", "submission_order": 1, "result": "WA", "execution_time": "1518 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACDAA53FA3A8D", "submission_order": 2, "result": "AC", "execution_time": "1636 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACEA91593F9D3", "submission_order": 1, "result": "AC", "execution_time": "1452 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 1, "result": "RE", "execution_time": "1182 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 2, "result": "RE", "execution_time": "1424 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 3, "result": "RE", "execution_time": "1185 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 4, "result": "RE", "execution_time": "1252 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.i(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 5, "result": "RE", "execution_time": "1525 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.i(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 6, "result": "WA", "execution_time": "1442 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 7, "result": "WA", "execution_time": "1235 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 8, "result": "WA", "execution_time": "1962 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ACF6043CAA0A9", "submission_order": 9, "result": "AC", "execution_time": "1645 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD12A9443C6AC", "submission_order": 1, "result": "RE", "execution_time": "1451 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x()\n    qc.z()\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD12A9443C6AC", "submission_order": 2, "result": "WA", "execution_time": "1513 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD4EA861A3B58", "submission_order": 1, "result": "AC", "execution_time": "1198 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD549BCBD4280", "submission_order": 1, "result": "WA", "execution_time": "1662 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD549BCBD4280", "submission_order": 2, "result": "AC", "execution_time": "1214 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD64DA09AAF10", "submission_order": 1, "result": "AC", "execution_time": "1560 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, YGate, ZGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.append(XGate(), [0])\n    qc.append(YGate(), [0])\n    qc.append(XGate(), [0])\n    qc.append(ZGate(), [0])\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD77908D4BA34", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n \n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC003_A1", "user": "AD9F48B9C08EA", "submission_order": 1, "result": "WA", "execution_time": "1248 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD9F48B9C08EA", "submission_order": 2, "result": "WA", "execution_time": "1219 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AD9F48B9C08EA", "submission_order": 3, "result": "AC", "execution_time": "1479 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ADC8682B47968", "submission_order": 1, "result": "AC", "execution_time": "1705 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "ADCEF8C5F4A87", "submission_order": 1, "result": "AC", "execution_time": "1530 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    #LLevar al estado 1\n    qc.x(0)\n    # Introducir la fase i\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AE0E3674C5BF0", "submission_order": 1, "result": "AC", "execution_time": "1788 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AE337860BC4A6", "submission_order": 1, "result": "AC", "execution_time": "1529 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.s(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AE4D9630D11C3", "submission_order": 1, "result": "AC", "execution_time": "1444 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AE74A030D39F2", "submission_order": 1, "result": "WA", "execution_time": "1966 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AE74A030D39F2", "submission_order": 2, "result": "AC", "execution_time": "1945 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AECCFFB0C0944", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AECCFFB0C0944", "submission_order": 2, "result": "AC", "execution_time": "1547 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AEEE491908402", "submission_order": 1, "result": "AC", "execution_time": "1219 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AEF96433AEE32", "submission_order": 1, "result": "AC", "execution_time": "1641 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AF40D965A29F3", "submission_order": 1, "result": "WA", "execution_time": "1883 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.x(0)\n    qc.rz(pi/2, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AF40D965A29F3", "submission_order": 2, "result": "AC", "execution_time": "1724 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.x(0)\n    qc.rz(pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AF4733F375FC5", "submission_order": 1, "result": "RE", "execution_time": "1421 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(3*np.pi, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AF4733F375FC5", "submission_order": 2, "result": "AC", "execution_time": "1298 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.rx(3*np.pi, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AF613C461ED12", "submission_order": 1, "result": "AC", "execution_time": "1675 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n    return qc\n'''"}
{"problem": "QPC003_A1", "user": "AFD6F89466A15", "submission_order": 1, "result": "AC", "execution_time": "1241 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.rz(math.pi,0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A04965D5FAD08", "submission_order": 1, "result": "AC", "execution_time": "1452 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A05986C4AEE24", "submission_order": 1, "result": "AC", "execution_time": "1592 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A06CB275FA4AC", "submission_order": 1, "result": "WA", "execution_time": "1464 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # |0⟩を|+⟩に変換（アダマールゲート）\n    qc.h(0)\n    # 1量子ビット目から2量子ビット目へのCNOT\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A06CB275FA4AC", "submission_order": 2, "result": "WA", "execution_time": "1566 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # 量子ビット0を|1⟩にするためにXゲートを適用\n    qc.x(0)\n    # 量子ビット0を制御ビット、量子ビット1をターゲットとしてCNOTを適用\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A06CB275FA4AC", "submission_order": 3, "result": "WA", "execution_time": "1231 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # |0⟩を|1⟩にするためにXゲートを適用\n    qc.x(0)\n    # 量子ビット0を制御ビット、量子ビット1をターゲットとしてCNOTを適用\n    qc.cx(0, 1)\n    # 量子ビット0を|+⟩にするためにHゲートを適用\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A06CB275FA4AC", "submission_order": 4, "result": "WA", "execution_time": "1502 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # 量子ビット0を|0⟩から|1⟩にするためにXゲートを適用\n    qc.x(0)\n    # 量子ビット0を制御ビット、量子ビット1をターゲットとしてCNOTを適用\n    qc.cx(0, 1)\n    # 量子ビット0を|0⟩に戻すためにXゲートを適用\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A06CB275FA4AC", "submission_order": 5, "result": "WA", "execution_time": "1568 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # 量子ビット0を|0⟩から|1⟩にするためにXゲートを適用\n    qc.x(0)\n    # 量子ビット0にHゲートを適用して|+⟩状態を生成\n    qc.h(0)\n    # 量子ビット0を制御ビット、量子ビット1をターゲットとしてCNOTを適用\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A06CB275FA4AC", "submission_order": 6, "result": "AC", "execution_time": "1492 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # 量子ビット0を|1⟩にするためにXゲートを適用\n    qc.x(0)  \n    # 量子ビット1にHゲートを適用して|+⟩状態を生成\n    qc.h(1)  \n    # CNOTゲートでエンタングルメントを生成\n    qc.cx(1, 0)  \n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A08CCCE1D9EF4", "submission_order": 1, "result": "WA", "execution_time": "1533 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A08CCCE1D9EF4", "submission_order": 2, "result": "AC", "execution_time": "1673 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A09611DF6C7FA", "submission_order": 1, "result": "WA", "execution_time": "1214 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A09611DF6C7FA", "submission_order": 2, "result": "AC", "execution_time": "1643 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    qc.x(1)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A0A0A017992CF", "submission_order": 1, "result": "AC", "execution_time": "1534 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A0C2B8A74C8D7", "submission_order": 1, "result": "WA", "execution_time": "1597 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A0C2B8A74C8D7", "submission_order": 2, "result": "AC", "execution_time": "1274 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A0C5C7CB1507D", "submission_order": 1, "result": "AC", "execution_time": "1591 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#from qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.x(0)\n    qc.cx(1,0)\n    return qc\n\n#if __name__ == \"__main__\":\n#    qc = solve()\n#    print(Statevector(qc))\n'''"}
{"problem": "QPC003_A2", "user": "A1254C08FF7B5", "submission_order": 1, "result": "WA", "execution_time": "1493 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A1254C08FF7B5", "submission_order": 2, "result": "WA", "execution_time": "1631 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A1254C08FF7B5", "submission_order": 3, "result": "WA", "execution_time": "1495 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A1254C08FF7B5", "submission_order": 4, "result": "WA", "execution_time": "1207 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A1254C08FF7B5", "submission_order": 5, "result": "AC", "execution_time": "1632 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A12DD0C799898", "submission_order": 1, "result": "AC", "execution_time": "1593 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A130C7025A21D", "submission_order": 1, "result": "WA", "execution_time": "1601 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A130C7025A21D", "submission_order": 2, "result": "AC", "execution_time": "1573 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n  \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A1484F48CAB30", "submission_order": 1, "result": "AC", "execution_time": "1403 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A16FED3EFE13F", "submission_order": 1, "result": "AC", "execution_time": "2060 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A194AC8CA5258", "submission_order": 1, "result": "AC", "execution_time": "1628 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A1AC9ADEAE74D", "submission_order": 1, "result": "WA", "execution_time": "1607 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A1AC9ADEAE74D", "submission_order": 2, "result": "AC", "execution_time": "1691 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A1B82B62663F8", "submission_order": 1, "result": "AC", "execution_time": "1841 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A232C81383715", "submission_order": 1, "result": "AC", "execution_time": "1468 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A2B50825F0F0F", "submission_order": 1, "result": "AC", "execution_time": "1653 ms", "memory": "155 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A2CBC00BC4D36", "submission_order": 1, "result": "WA", "execution_time": "2067 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    # Apply CNOT gate with the first qubit as control and the second qubit as target\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A2CBC00BC4D36", "submission_order": 2, "result": "WA", "execution_time": "2014 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Apply a NOT gate to the first qubit to create |1>\n    qc.x(0)  # This transforms |00> to |10>\n    \n    # Step 2: Apply a Hadamard gate to the second qubit to create superposition\n    qc.h(1)  # This transforms |10> to (|10> + |11>)/sqrt(2)\n    \n    # Step 3: Apply a NOT gate to the first qubit to create |01>\n    qc.x(0)  # This transforms (|10> + |11>)/sqrt(2) to (|01> + |10>)/sqrt(2)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A2CBC00BC4D36", "submission_order": 3, "result": "AC", "execution_time": "2047 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Step 1: X on qubit 0\n    qc.x(0)\n    # Step 2: H on qubit 1\n    qc.h(1)\n    # Step 3: CNOT(control=1, target=0)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A31F8B8E1A10E", "submission_order": 1, "result": "AC", "execution_time": "1639 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A34C7EA1AC2FB", "submission_order": 1, "result": "AC", "execution_time": "1822 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A36ED57A95B4E", "submission_order": 1, "result": "RE", "execution_time": "1303 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cnot(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A36ED57A95B4E", "submission_order": 2, "result": "AC", "execution_time": "1818 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3865575F031E", "submission_order": 1, "result": "AC", "execution_time": "1341 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3893469BCAD1", "submission_order": 1, "result": "AC", "execution_time": "1486 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3AE62AA3064C", "submission_order": 1, "result": "WA", "execution_time": "1779 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.x(0)\n    qc.cx(1, 0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3AE62AA3064C", "submission_order": 2, "result": "AC", "execution_time": "1586 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.x(0)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 1, "result": "WA", "execution_time": "1686 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.y(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 2, "result": "WA", "execution_time": "1495 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 3, "result": "WA", "execution_time": "1534 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 4, "result": "WA", "execution_time": "1519 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 5, "result": "WA", "execution_time": "1244 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 6, "result": "WA", "execution_time": "1782 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 7, "result": "WA", "execution_time": "1529 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cy(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 8, "result": "WA", "execution_time": "1659 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.dcx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3D54A05B786C", "submission_order": 9, "result": "AC", "execution_time": "1259 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3F94DF616002", "submission_order": 1, "result": "WA", "execution_time": "2076 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3F94DF616002", "submission_order": 2, "result": "WA", "execution_time": "2030 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A3F94DF616002", "submission_order": 3, "result": "AC", "execution_time": "2113 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A41B6E2A53A0F", "submission_order": 1, "result": "AC", "execution_time": "1627 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A41F3E0EACC91", "submission_order": 1, "result": "AC", "execution_time": "1531 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A4516428ABE76", "submission_order": 1, "result": "AC", "execution_time": "1869 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A4B4409C1BF3D", "submission_order": 1, "result": "AC", "execution_time": "1554 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(0)\n\n\n    qc.h(1)\n\n\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A4B46F0E965B7", "submission_order": 1, "result": "AC", "execution_time": "1463 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A52957BAD891B", "submission_order": 1, "result": "AC", "execution_time": "1544 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A56E39BF6B90A", "submission_order": 1, "result": "AC", "execution_time": "1859 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A5844235099A6", "submission_order": 1, "result": "WA", "execution_time": "1690 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A5844235099A6", "submission_order": 2, "result": "AC", "execution_time": "1340 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A5D0909F8E1DE", "submission_order": 1, "result": "AC", "execution_time": "1267 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A5E4100E74B0E", "submission_order": 1, "result": "AC", "execution_time": "1287 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A2", "user": "A5E815882253C", "submission_order": 1, "result": "AC", "execution_time": "1528 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n#from qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.x(1)\n    qc.cx(0,1)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A2", "user": "A60CDF04B2554", "submission_order": 1, "result": "AC", "execution_time": "1639 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1) # 01\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A61D520C58DBB", "submission_order": 1, "result": "AC", "execution_time": "1606 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A626B9EE66501", "submission_order": 1, "result": "AC", "execution_time": "1435 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A633AA99B4061", "submission_order": 1, "result": "AC", "execution_time": "1265 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A6403A484E800", "submission_order": 1, "result": "WA", "execution_time": "1442 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A2", "user": "A6403A484E800", "submission_order": 2, "result": "AC", "execution_time": "1444 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A2", "user": "A6680778704A8", "submission_order": 1, "result": "WA", "execution_time": "1501 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A6680778704A8", "submission_order": 2, "result": "AC", "execution_time": "1536 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A68B2251E466B", "submission_order": 1, "result": "AC", "execution_time": "1289 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # Ponerlo en el estado 1\n    qc.x(0)\n    # Crear superposición\n    qc.h(1)\n    # Entrelazar ambos qubits\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A6A32A7653E25", "submission_order": 1, "result": "RE", "execution_time": "1717 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2, 3, [1, 3])\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     # sv = Statevector.from_label('01000')\n#     # print(sv.evolve(qc))\n'''"}
{"problem": "QPC003_A2", "user": "A6A32A7653E25", "submission_order": 2, "result": "AC", "execution_time": "1824 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n#     qc = solve(2, 3, [1, 3])\n#     # sv = Statevector(qc)\n#     # print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     # sv = Statevector.from_label('01000')\n#     # print(sv.evolve(qc))\n'''"}
{"problem": "QPC003_A2", "user": "A6ACB312FC30A", "submission_order": 1, "result": "WA", "execution_time": "1367 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.ch(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A6ACB312FC30A", "submission_order": 2, "result": "WA", "execution_time": "1513 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A6ACB312FC30A", "submission_order": 3, "result": "AC", "execution_time": "1214 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A6B12D00BB51A", "submission_order": 1, "result": "AC", "execution_time": "1359 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A6FCFDE927FC8", "submission_order": 1, "result": "WA", "execution_time": "1416 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A6FCFDE927FC8", "submission_order": 2, "result": "AC", "execution_time": "1515 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A7088373DADE5", "submission_order": 1, "result": "AC", "execution_time": "1486 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    \n    qc.x(0)\n    qc.h(1)\n    qc.cx(1, 0)\n \n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A710834FDF1B4", "submission_order": 1, "result": "WA", "execution_time": "1644 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A710834FDF1B4", "submission_order": 2, "result": "WA", "execution_time": "1479 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A710834FDF1B4", "submission_order": 3, "result": "WA", "execution_time": "1414 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A710834FDF1B4", "submission_order": 4, "result": "AC", "execution_time": "1558 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A7625A9DBF0B2", "submission_order": 1, "result": "AC", "execution_time": "1633 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A76349D465C6A", "submission_order": 1, "result": "RE", "execution_time": "1581 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A76349D465C6A", "submission_order": 2, "result": "AC", "execution_time": "1796 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A76FBEDC422E3", "submission_order": 1, "result": "AC", "execution_time": "1467 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A7B21B245DC66", "submission_order": 1, "result": "AC", "execution_time": "1559 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A7BBD4FF761F4", "submission_order": 1, "result": "AC", "execution_time": "2009 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A7E1299EC97F0", "submission_order": 1, "result": "AC", "execution_time": "1251 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A80AA99B377D8", "submission_order": 1, "result": "AC", "execution_time": "1436 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A82362AC30FF6", "submission_order": 1, "result": "AC", "execution_time": "1283 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)       \n    qc.cx(0, 1)   \n    qc.x(1) \n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8436D48F6A45", "submission_order": 1, "result": "AC", "execution_time": "1569 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A87082985918E", "submission_order": 1, "result": "AC", "execution_time": "1504 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A89215C732AC6", "submission_order": 1, "result": "WA", "execution_time": "1652 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A89215C732AC6", "submission_order": 2, "result": "WA", "execution_time": "1652 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A89215C732AC6", "submission_order": 3, "result": "WA", "execution_time": "1220 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A89215C732AC6", "submission_order": 4, "result": "RE", "execution_time": "1506 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A89215C732AC6", "submission_order": 5, "result": "RE", "execution_time": "1393 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A89215C732AC6", "submission_order": 6, "result": "RE", "execution_time": "1359 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A89BAA378B87C", "submission_order": 1, "result": "AC", "execution_time": "1217 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8A9B08DC81FE", "submission_order": 1, "result": "RE", "execution_time": "1530 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx([0,1])\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8A9B08DC81FE", "submission_order": 2, "result": "AC", "execution_time": "1511 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8C32E4C68DBB", "submission_order": 1, "result": "AC", "execution_time": "1722 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8C4AC591737D", "submission_order": 1, "result": "AC", "execution_time": "1460 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8C8A6D355C33", "submission_order": 1, "result": "AC", "execution_time": "1593 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8D8D7A7CD558", "submission_order": 1, "result": "WA", "execution_time": "1600 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8D8D7A7CD558", "submission_order": 2, "result": "WA", "execution_time": "1477 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A8EF7A0ACF10B", "submission_order": 1, "result": "AC", "execution_time": "1495 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(1)\n    qc.x(0)\n    qc.cx(1,0)\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9025E89BE091", "submission_order": 1, "result": "AC", "execution_time": "1415 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A911A7295441A", "submission_order": 1, "result": "AC", "execution_time": "1225 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A915F979C6F34", "submission_order": 1, "result": "RE", "execution_time": "1178 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.X(0)\n    qc.CX(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A915F979C6F34", "submission_order": 2, "result": "RE", "execution_time": "1519 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.X(1)\n    qc.CX(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A915F979C6F34", "submission_order": 3, "result": "AC", "execution_time": "1489 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A93A5B08A5F01", "submission_order": 1, "result": "AC", "execution_time": "1846 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A93EBF9D0588D", "submission_order": 1, "result": "WA", "execution_time": "1469 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, HGate\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.append(HGate(), [0])\n    qc.append(HGate(), [1])\n    qc.append(XGate(), [0])\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A93EBF9D0588D", "submission_order": 2, "result": "WA", "execution_time": "1283 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, HGate\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.append(HGate(), [0])\n    qc.append(HGate(), [1])\n    qc.append(XGate(), [1])\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A93EBF9D0588D", "submission_order": 3, "result": "WA", "execution_time": "1589 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, HGate, CXGate\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.append(HGate(), [0])\n    qc.append(XGate(), [1])\n    qc.append(CXGate(), [0, 1])\n    qc.append(XGate(), [0])\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A93EBF9D0588D", "submission_order": 4, "result": "WA", "execution_time": "1542 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, HGate, CXGate\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.append(XGate(), [0])\n    qc.append(HGate(), [1])\n    qc.append(CXGate(), [0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A93EBF9D0588D", "submission_order": 5, "result": "AC", "execution_time": "1530 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, HGate, CXGate\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.append(HGate(), [0])\n    qc.append(XGate(), [1])\n    qc.append(CXGate(), [0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A95A240114481", "submission_order": 1, "result": "AC", "execution_time": "1231 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9644B2ED9CE1", "submission_order": 1, "result": "AC", "execution_time": "1224 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9688E3E7251E", "submission_order": 1, "result": "AC", "execution_time": "1580 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n     \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A96E0750EFA77", "submission_order": 1, "result": "WA", "execution_time": "1345 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A96E0750EFA77", "submission_order": 2, "result": "WA", "execution_time": "1431 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A96E0750EFA77", "submission_order": 3, "result": "RE", "execution_time": "1458 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A96E0750EFA77", "submission_order": 4, "result": "WA", "execution_time": "1484 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A96E0750EFA77", "submission_order": 5, "result": "AC", "execution_time": "1450 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n     # 1. 量子ビット0にアダマールゲートを適用\n    qc.h(0)\n\n    # 2. CNOTゲートを適用（量子ビット0を制御、量子ビット1をターゲット）\n    qc.cx(0, 1)\n\n    # 3. Xゲートを適用（量子ビット1を反転）\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A96FBF2FA7055", "submission_order": 1, "result": "AC", "execution_time": "1481 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9750CC658AF2", "submission_order": 1, "result": "AC", "execution_time": "1566 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A985AE8AFEB3F", "submission_order": 1, "result": "WA", "execution_time": "1652 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A985AE8AFEB3F", "submission_order": 2, "result": "WA", "execution_time": "1714 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A985AE8AFEB3F", "submission_order": 3, "result": "AC", "execution_time": "1291 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9A77C497E80C", "submission_order": 1, "result": "AC", "execution_time": "1594 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9A9A36229576", "submission_order": 1, "result": "WA", "execution_time": "1457 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9A9A36229576", "submission_order": 2, "result": "WA", "execution_time": "1573 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9A9A36229576", "submission_order": 3, "result": "AC", "execution_time": "1609 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9C0FC8CE3EBF", "submission_order": 1, "result": "AC", "execution_time": "1593 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9C4D0A4CF2D2", "submission_order": 1, "result": "AC", "execution_time": "1736 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1) \n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9D421C435B63", "submission_order": 1, "result": "AC", "execution_time": "1611 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9EC6BEFC41C9", "submission_order": 1, "result": "RE", "execution_time": "1451 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(1)\n    qc.x(0)\n    qc.cnot(0,0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9EC6BEFC41C9", "submission_order": 2, "result": "RE", "execution_time": "1307 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.swap(1)\n    qc.x(0)\n    qc.cx(0,0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9EC6BEFC41C9", "submission_order": 3, "result": "RE", "execution_time": "1376 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.x(0)\n    qc.cx(0,0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "A9EC6BEFC41C9", "submission_order": 4, "result": "AC", "execution_time": "1476 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AA1AD57DBEA5F", "submission_order": 1, "result": "WA", "execution_time": "1848 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AA1AD57DBEA5F", "submission_order": 2, "result": "WA", "execution_time": "1998 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AA1AD57DBEA5F", "submission_order": 3, "result": "WA", "execution_time": "1908 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AA1AD57DBEA5F", "submission_order": 4, "result": "WA", "execution_time": "2004 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1,0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AA1AD57DBEA5F", "submission_order": 5, "result": "AC", "execution_time": "1905 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AAC5220047E3B", "submission_order": 1, "result": "AC", "execution_time": "1554 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AACCD1524DADC", "submission_order": 1, "result": "AC", "execution_time": "2283 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AADFF3DE13E8F", "submission_order": 1, "result": "AC", "execution_time": "1337 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AAE886AAC172C", "submission_order": 1, "result": "AC", "execution_time": "1464 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AAEB571004798", "submission_order": 1, "result": "AC", "execution_time": "1296 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB12B0D2AC0AF", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB1881365372E", "submission_order": 1, "result": "AC", "execution_time": "1615 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB36DE84CCF22", "submission_order": 1, "result": "AC", "execution_time": "2052 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\n\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(2)\n  qc.h(0)\n  qc.cx(0, 1)\n  qc.x(1)\n\n\n  return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB601D49D59D3", "submission_order": 1, "result": "AC", "execution_time": "1996 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB68C48E0F74C", "submission_order": 1, "result": "AC", "execution_time": "1244 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB7CF3D1ECE71", "submission_order": 1, "result": "WA", "execution_time": "1687 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB7CF3D1ECE71", "submission_order": 2, "result": "AC", "execution_time": "1479 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB969C3739FE2", "submission_order": 1, "result": "WA", "execution_time": "1504 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB969C3739FE2", "submission_order": 2, "result": "WA", "execution_time": "1544 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB969C3739FE2", "submission_order": 3, "result": "WA", "execution_time": "1263 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AB969C3739FE2", "submission_order": 4, "result": "AC", "execution_time": "1243 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(1)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ABC1F94F3F40C", "submission_order": 1, "result": "WA", "execution_time": "1537 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ABC1F94F3F40C", "submission_order": 2, "result": "AC", "execution_time": "1585 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ABCFF15881764", "submission_order": 1, "result": "WA", "execution_time": "1665 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ABCFF15881764", "submission_order": 2, "result": "AC", "execution_time": "1764 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AC28BB1C220D4", "submission_order": 1, "result": "RE", "execution_time": "1471 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    wc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AC28BB1C220D4", "submission_order": 2, "result": "AC", "execution_time": "1277 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AC38E231D43F6", "submission_order": 1, "result": "AC", "execution_time": "1572 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve():\n\tqc = QuantumCircuit(2)\n\tqc.h(0)\n\tqc.x(0)\n\tqc.cx(0, 1)\n\tqc.x(0)\n\treturn qc\n'''"}
{"problem": "QPC003_A2", "user": "AC62163D92AA7", "submission_order": 1, "result": "AC", "execution_time": "1572 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    \n    \n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AC8B263B0A8F6", "submission_order": 1, "result": "AC", "execution_time": "1509 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACA3FCD8B940D", "submission_order": 1, "result": "AC", "execution_time": "1551 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACD9BD291E9CF", "submission_order": 1, "result": "AC", "execution_time": "1652 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACEEA59BFF00E", "submission_order": 1, "result": "WA", "execution_time": "1785 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACEEA59BFF00E", "submission_order": 2, "result": "WA", "execution_time": "1604 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.z(1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACEEA59BFF00E", "submission_order": 3, "result": "WA", "execution_time": "1521 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACEEA59BFF00E", "submission_order": 4, "result": "WA", "execution_time": "1256 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACEEA59BFF00E", "submission_order": 5, "result": "WA", "execution_time": "1465 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.cx(1,0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACEEA59BFF00E", "submission_order": 6, "result": "WA", "execution_time": "1561 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(1)\n    qc.cx(1,0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ACEEA59BFF00E", "submission_order": 7, "result": "AC", "execution_time": "1650 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD1A3C273F93A", "submission_order": 1, "result": "WA", "execution_time": "1513 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n \n    qc.h(0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD1A3C273F93A", "submission_order": 2, "result": "AC", "execution_time": "1528 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n \n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD267B1764AE1", "submission_order": 1, "result": "AC", "execution_time": "1272 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD3327C6D2B63", "submission_order": 1, "result": "AC", "execution_time": "1325 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 1, "result": "WA", "execution_time": "1271 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 2, "result": "WA", "execution_time": "1580 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 3, "result": "RE", "execution_time": "1457 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.cx(1, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 4, "result": "WA", "execution_time": "1234 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 5, "result": "RE", "execution_time": "1313 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 1)\n#    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 6, "result": "RE", "execution_time": "1297 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(1, 1)\n#    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 7, "result": "WA", "execution_time": "1421 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n#    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 8, "result": "WA", "execution_time": "1525 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n#    qc.cx(1, 0)\n#    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 9, "result": "WA", "execution_time": "1558 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1, 0)\n#    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 10, "result": "WA", "execution_time": "1477 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n#    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 11, "result": "WA", "execution_time": "1223 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n#    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 12, "result": "WA", "execution_time": "1571 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1, 0)\n#    qc.cx(0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 13, "result": "WA", "execution_time": "1540 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n#    qc.cx(1, 0)\n    qc.cx(0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 14, "result": "WA", "execution_time": "1989 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n#    qc.cx(1, 0)\n    qc.cx(0, 1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 15, "result": "WA", "execution_time": "1273 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1, 0)\n#    qc.cx(0, 1)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 16, "result": "WA", "execution_time": "1222 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1, 0)\n#    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 17, "result": "WA", "execution_time": "1563 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n#    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 18, "result": "WA", "execution_time": "1590 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 19, "result": "WA", "execution_time": "1356 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 20, "result": "WA", "execution_time": "1490 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 21, "result": "RE", "execution_time": "1500 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h()\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 22, "result": "WA", "execution_time": "1476 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AD9E795BFC5B1", "submission_order": 23, "result": "AC", "execution_time": "1714 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.h(0)\n#    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ADB45D95F29E2", "submission_order": 1, "result": "AC", "execution_time": "1506 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "ADCF2B8F90AA1", "submission_order": 1, "result": "AC", "execution_time": "1497 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AE1EF0F1BBDDB", "submission_order": 1, "result": "AC", "execution_time": "1201 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AE6120DC47C12", "submission_order": 1, "result": "AC", "execution_time": "1654 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AE7DD3D63337B", "submission_order": 1, "result": "WA", "execution_time": "1554 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AED1C30BCCEAC", "submission_order": 1, "result": "AC", "execution_time": "1498 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AF0D3228D2D91", "submission_order": 1, "result": "RE", "execution_time": "1438 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, CXGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.append(HGate(), [0])\n    qc.append(CXGate(), [0, 1])\n    qc.append(XGate(), [0])\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AF0D3228D2D91", "submission_order": 2, "result": "AC", "execution_time": "1448 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, CXGate, XGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.append(HGate(), [0])\n    qc.append(CXGate(), [0, 1])\n    qc.append(XGate(), [0])\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AF14ACE7DF514", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n# from qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    print(qc)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A2", "user": "AF2FFA0AFD666", "submission_order": 1, "result": "AC", "execution_time": "1609 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AF33885AC80F4", "submission_order": 1, "result": "AC", "execution_time": "1593 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AF38C524C57EE", "submission_order": 1, "result": "AC", "execution_time": "2069 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A2", "user": "AFC92362B82E9", "submission_order": 1, "result": "AC", "execution_time": "1927 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A0054C2955850", "submission_order": 1, "result": "AC", "execution_time": "1260 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    theta = 2*np.arccos(1/np.sqrt(3))\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,2)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A005F96768946", "submission_order": 1, "result": "RE", "execution_time": "1435 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(2)\n    qc.ch(0, 2)\n    qc.ccx(2, 0, 1)\n    qc.cx(1, 2)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A005F96768946", "submission_order": 2, "result": "WA", "execution_time": "1563 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(2)\n    qc.ch(0, 2)\n    qc.ccx(2, 0, 1)\n    qc.cx(1, 2)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A005F96768946", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.h(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 2)\n    qc.x(2)\n    qc.ccx(2, 0, 1)\n    qc.cx(1, 2)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A005F96768946", "submission_order": 4, "result": "WA", "execution_time": "1329 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.h(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 2)\n    qc.x(2)\n    qc.ccx(2, 0, 1)\n    qc.cx(1, 2)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A005F96768946", "submission_order": 5, "result": "AC", "execution_time": "1383 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 2)\n    qc.x(2)\n    qc.ccx(2, 0, 1)\n    qc.cx(1, 2)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A106780A6C379", "submission_order": 1, "result": "RE", "execution_time": "1176 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    \n    qc.x(0)\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.ch(1,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A106780A6C379", "submission_order": 2, "result": "RE", "execution_time": "1446 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    \n    qc.x(0)\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.cx(1,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A106780A6C379", "submission_order": 3, "result": "RE", "execution_time": "1202 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    \n    qc.ry(theta, 0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.c(1,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A106780A6C379", "submission_order": 4, "result": "RE", "execution_time": "1384 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    \n\n    qc.ry(theta, 0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.cx(1,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A106780A6C379", "submission_order": 5, "result": "RE", "execution_time": "1583 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.cx(0,1)\n    qc.ch(1,2)\n    qc.cx(2,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A106780A6C379", "submission_order": 6, "result": "AC", "execution_time": "1613 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.cx(0,1)\n    qc.ch(1,2)\n    qc.cx(2,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A11D457DA2DA7", "submission_order": 1, "result": "AC", "execution_time": "1848 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*math.asin(1/math.sqrt(3)),0)\n    qc.x(0)\n    qc.ch(0,1)\n    qc.x(1)\n    qc.cx(1,2)\n    qc.cx(0,2)\n    qc.x(1)\n    qc.x(0)\n    qc.x(2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A166FB0C92E15", "submission_order": 1, "result": "AC", "execution_time": "1498 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = acos(-1/3)\n    qc.u(theta, 0 , 0, 0)\n    qc.ch(0, 1)\n    qc.ccx(*[0, 1], 2)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A1868421FFDA4", "submission_order": 1, "result": "RE", "execution_time": "1456 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 1)\n    qc.x(0)\n    qc.ch(1, 2)\n    qc.ccx(2, 1, 0)\n    qc.cx(2, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A1868421FFDA4", "submission_order": 2, "result": "AC", "execution_time": "1215 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 1)\n    qc.x(0)\n    qc.ch(1, 2)\n    qc.ccx(2, 1, 0)\n    qc.cx(2, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 1, "result": "RE", "execution_time": "1568 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    from math import pi\n    qc.ry(0, 2*pi/3)\n    qc.cnot(0,1)\n    qc.cnot(0,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 2, "result": "RE", "execution_time": "1498 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    from math import pi\n    qc.ry(2*pi/3, 0)\n    qc.cnot(0,1)\n    qc.cnot(0,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 3, "result": "RE", "execution_time": "1569 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    from math import pi\n    qc.ry(2*pi/3, 0)\n    qc.cnot(0,1)\n    qc.cnot(0,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 4, "result": "RE", "execution_time": "1155 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    from numpy import pi\n    qc.ry(2*pi/3, 0)\n    qc.cnot(0,1)\n    qc.cnot(0,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 5, "result": "WA", "execution_time": "1668 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    from numpy import pi\n    qc.ry(2*pi/3, 0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 6, "result": "WA", "execution_time": "1220 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    from numpy import pi\n    qc.ry(pi/3, 0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 7, "result": "RE", "execution_time": "1179 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0) \n    qc.cx(0, 1)  \n    qc.cx(0, 2)  \n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 8, "result": "WA", "execution_time": "1555 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    qc.h(0) \n    qc.cx(0, 1)  \n    qc.cx(0, 2)  \n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 9, "result": "WA", "execution_time": "1641 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    qc.h(0) \n    qc.cx(0, 1)  \n    qc.cx(0, 2)  \n    theta = 2 * math.tan(1 / math.sqrt(2))\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 10, "result": "WA", "execution_time": "1598 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    qc.h(0) \n    qc.cx(0, 1)  \n    qc.cx(0, 2)  \n    theta = math.tan(1 / math.sqrt(2))\n    qc.ry(theta, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.h(0, 2)\n    qc.x(0)\n    qc.x(2)\n    qc.ccnot(0, 2, 1)\n    qc.x(2)\n    qc.x(0)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 12, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3))\n    qc.ry(theta, 0)\n    qc.ch(0, 2)\n    qc.x(0)\n    qc.x(2)\n    qc.ccnot(0, 2, 1)\n    qc.x(2)\n    qc.x(0)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 13, "result": "RE", "execution_time": "1159 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 2)\n    qc.x(0)\n    qc.x(2)\n    qc.ccnot(0, 2, 1)\n    qc.x(2)\n    qc.x(0)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 14, "result": "WA", "execution_time": "2159 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 2)\n    qc.x(0)\n    qc.x(2)\n    qc.ccx(0, 2, 1)\n    qc.x(2)\n    qc.x(0)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 15, "result": "WA", "execution_time": "1414 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(2, 0)\n    qc.x(0)\n    qc.x(2)\n    qc.ccx(0, 2, 1)\n    qc.x(2)\n    qc.x(0)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2027F8BE110E", "submission_order": 16, "result": "AC", "execution_time": "1487 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    import math\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n    qc.ry(theta, 2)\n    qc.ch(2, 0)\n    qc.x(0)\n    qc.x(2)\n    qc.ccx(0, 2, 1)\n    qc.x(2)\n    qc.x(0)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A20D108D98D68", "submission_order": 1, "result": "WA", "execution_time": "1556 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2139F9959673", "submission_order": 1, "result": "AC", "execution_time": "1601 ms", "memory": "154 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    acos,\n    # atan2,\n    sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(acos(1 / sqrt(3)) * 2, 0)\n    qc.cry(acos(1 / sqrt(2)) * 2, 0, 1)\n    qc.ccx(0, 1, 2)\n    qc.x(1)\n    qc.cx(0, 1)\n    qc.cx(2, 0)\n    qc.cx(2, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A25D2728148ED", "submission_order": 1, "result": "AC", "execution_time": "1584 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(1.91063324, 0)\n\n\n    qc.ch(0,1)\n    qc.cx(1,2)\n    qc.cx(0,1)\n    qc.x(0) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2619FBF8C64C", "submission_order": 1, "result": "WA", "execution_time": "1472 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(1,0)\n    qc.cx(2,1)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2619FBF8C64C", "submission_order": 2, "result": "WA", "execution_time": "1217 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(1,0)\n    qc.cx(2,1)\n    qc.cx(1,0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2619FBF8C64C", "submission_order": 3, "result": "AC", "execution_time": "1446 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,2)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 1, "result": "WA", "execution_time": "1615 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 2, "result": "WA", "execution_time": "1464 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.x(2)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 3, "result": "RE", "execution_time": "1227 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 4, "result": "RE", "execution_time": "1503 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 5, "result": "RE", "execution_time": "1473 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 6, "result": "RE", "execution_time": "1419 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 7, "result": "RE", "execution_time": "1166 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    # qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 8, "result": "RE", "execution_time": "1423 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    # qc.ch(0, 1)\n    # qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 9, "result": "WA", "execution_time": "1641 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 10, "result": "WA", "execution_time": "1566 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 11, "result": "WA", "execution_time": "1798 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 12, "result": "WA", "execution_time": "1556 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.x(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 13, "result": "WA", "execution_time": "1704 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.x(0)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    # qc.cx(1, 0)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 14, "result": "WA", "execution_time": "1586 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 1)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 15, "result": "WA", "execution_time": "1543 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 1)\n    qc.ch(0, 1)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 16, "result": "WA", "execution_time": "1484 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 1)\n    qc.ch(1, 0)\n    qc.cx(2, 1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2B309FADBB7B", "submission_order": 17, "result": "WA", "execution_time": "1242 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 1)\n    qc.ch(1, 0)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A2DCDDEEC2319", "submission_order": 1, "result": "AC", "execution_time": "1207 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1,2)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A3024B7931760", "submission_order": 1, "result": "AC", "execution_time": "1473 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    theta = 2*math.atan(math.sqrt(2))\n    \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A34D22B8513D8", "submission_order": 1, "result": "RE", "execution_time": "1143 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc = QuantumCircuit(2)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    for i in range(3):\n        qc.x(i)\n    \n    qc.ccx(0,0,1)\n\n    for i in range(3):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A34D22B8513D8", "submission_order": 2, "result": "RE", "execution_time": "1508 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc = QuantumCircuit(2)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    for i in range(3):\n        qc.x(i)\n    \n    qc.ccx(0,1,2)\n\n    for i in range(3):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A34D22B8513D8", "submission_order": 3, "result": "RE", "execution_time": "1180 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    for i in range(3):\n        qc.x(i)\n    \n    qc.ccx(0,1,2)\n\n    for i in range(3):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A34D22B8513D8", "submission_order": 4, "result": "AC", "execution_time": "1489 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    \n    for i in range(3):\n        qc.x(i)\n    \n    qc.ccx(0,1,2)\n\n    for i in range(3):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A390D46654302", "submission_order": 1, "result": "RE", "execution_time": "1332 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.x(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A390D46654302", "submission_order": 2, "result": "RE", "execution_time": "1538 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(2))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.x(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A3975BB61D3C5", "submission_order": 1, "result": "RE", "execution_time": "1895 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(2*math.acos(1/math.sqrt(3)),0)\n    qc.h(0)\n    qc.s(0)\n    qc.ch(0,1)\n    qc.ccx(0,1,2)\n    qc.cx(0,1)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A3975BB61D3C5", "submission_order": 2, "result": "AC", "execution_time": "1843 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.rz(2*math.acos(1/math.sqrt(3)),0)\n    qc.h(0)\n    qc.s(0)\n    qc.ch(0,1)\n    qc.ccx(0,1,2)\n    qc.cx(0,1)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A398C5D36BE9D", "submission_order": 1, "result": "RE", "execution_time": "1669 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    # rotation arg theta\n    theta = 2 * math.acos(math.sqrt(1/3))\n    # make bell unitary\n    def CU_0110(QC):\n        QC.ch(2,0)\n        QC.ccx(2,0,1)\n        QC.cx(2,1)\n    def inv_CU_0110(QC):\n        QC.cx(2,1)\n        QC.ccx(2,0,1)\n        QC.ch(2,0)\n\n    # 量子回路を作成\n    qc = QuantumCircuit(3) \n\n    qc.ry(theta,2)\n    CU_0110(qc)\n    qc.x(2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A398C5D36BE9D", "submission_order": 2, "result": "AC", "execution_time": "1993 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    # rotation arg theta\n    theta = 2 * math.acos(math.sqrt(1/3))\n    # make bell unitary\n    def CU_0110(QC):\n        QC.ch(2,0)\n        QC.ccx(2,0,1)\n        QC.cx(2,1)\n    def inv_CU_0110(QC):\n        QC.cx(2,1)\n        QC.ccx(2,0,1)\n        QC.ch(2,0)\n\n    # 量子回路を作成\n    qc = QuantumCircuit(3) \n\n    qc.ry(theta,2)\n    CU_0110(qc)\n    qc.x(2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A3F45F06EAE77", "submission_order": 1, "result": "RE", "execution_time": "1470 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = math.acos(math.sqrt(1/3)) * 2\n    qc.ry(theta, 0)\n    qc.ch(0, 2)\n    qc.cx(2, 0)\n    qc.x(0)\n    qc.x(2)\n    qc.mcx([0, 2], 1)\n    qc.x(0)\n    qc.x(2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A3F45F06EAE77", "submission_order": 2, "result": "AC", "execution_time": "1405 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = math.acos(math.sqrt(1/3)) * 2\n    qc.ry(theta, 0)\n    qc.ch(0, 2)\n    qc.cx(2, 0)\n    qc.x(0)\n    qc.x(2)\n    qc.mcx([0, 2], 1)\n    qc.x(0)\n    qc.x(2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A3FB27B743CB3", "submission_order": 1, "result": "AC", "execution_time": "1769 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.x(0)\n    qc.ry(theta, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 2)\n    qc.cx(2, 1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A42A04F25CF7C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import *\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*arccos(1/sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A42A04F25CF7C", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import arccos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*arccos(1/sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0,1)\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A42A04F25CF7C", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import arccos, sqr\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(1.91063324, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0,1)\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A42A04F25CF7C", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import arccos, sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*arccos(1/sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0,1)\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A42A04F25CF7C", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import arccos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*arccos(1/sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0,1)\n    qc.x()\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A42A04F25CF7C", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import arccos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*arccos(1/sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A42A04F25CF7C", "submission_order": 7, "result": "AC", "execution_time": "1253 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(1.91063324, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4782F99E4DE6", "submission_order": 1, "result": "AC", "execution_time": "2036 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(math.sqrt(2)), 0, 1)\n    qc.cx(1, 0)\n    qc.cry(math.pi / 2, 1, 2)\n    qc.cx(2, 1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 1, "result": "RE", "execution_time": "1328 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.y(0)\n    qc.h(1)\n    qc.cnot(1,2)\n    qc.cnot(0,1)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 2, "result": "RE", "execution_time": "1430 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2*np.arccos(1/np.sqrt(3)),0)\n    qc.h(1)\n    qc.cnot(1,2)\n    qc.cnot(0,1)\n    qc.x()\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 3, "result": "RE", "execution_time": "1242 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.rx(2 * pi / 3, 0)\n    qc.h(1)\n    qc.cnot(1,2)\n    qc.cnot(0,1)\n    qc.x()\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 4, "result": "RE", "execution_time": "1500 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2 * np.arccos(1/np.sqrt(3)), 0)\n    qc.h(1)\n    qc.cnot(1,2)\n    qc.cnot(0,1)\n    qc.x()\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 5, "result": "RE", "execution_time": "1145 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(-2 * np.arccos(1/np.sqrt(3)), 0)\n    qc.h(1)\n    qc.cnot(1,2)\n    qc.cnot(0,1)\n    qc.x()\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(-2 * np.arccos(1.321, 0)\n    qc.h(1)\n    qc.cnot(1,2)\n    qc.cnot(0,1)\n    qc.x()\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 7, "result": "RE", "execution_time": "1163 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(1.321, 0)\n    qc.h(1)\n    qc.cnot(1,2)\n    qc.cnot(0,1)\n    qc.x()\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 8, "result": "RE", "execution_time": "1179 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.rx(2 * pi / 3, 0)\n\n# Step 3: Apply a CNOT gate from qubit 0 to qubit 1\n    qc.cx(0, 1)\n\n# Step 4: Apply a Controlled-RX rotation on qubit 2, controlled by qubit 1\n    qc.crx(2 * pi / 3, 1, 2)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 9, "result": "WA", "execution_time": "1233 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.rx(2 * pi / 3, 0)\n\n# Step 3: Apply a CNOT gate from qubit 0 to qubit 1\n    qc.cx(0, 1)\n\n# Step 4: Apply a Controlled-RX rotation on qubit 2, controlled by qubit 1\n    qc.crx(2 * pi / 3, 1, 2)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 10, "result": "WA", "execution_time": "1263 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    # Step 2: Apply an RX gate on the first qubit to create the initial superposition\n    qc.ry(2 * acos(1 / sqrt(3)), 0)\n\n# Step 3: Apply CNOT gate from qubit 0 to qubit 1\n    qc.cx(0, 1)\n\n# Step 4: Apply a CNOT gate from qubit 1 to qubit 2\n    qc.cx(1, 2)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 11, "result": "WA", "execution_time": "1211 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    # Step 2: Apply an RX gate on the first qubit to create the initial superposition\n    qc.ry(2 * acos(1 / sqrt(3)), 0)\n\n    qc.h(1)\n\n# Step 3: Apply CNOT gate from qubit 0 to qubit 1\n    qc.cx(0, 1)\n\n# Step 4: Apply a CNOT gate from qubit 1 to qubit 2\n    qc.cx(1, 2)\n\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 12, "result": "WA", "execution_time": "1258 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2 * acos(1 / sqrt(3)), 0)\n\n    qc.h(1)\n    qc.cx(1, 2)\n\n\n    qc.cx(1, 2)\n\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 13, "result": "WA", "execution_time": "1268 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2 * acos(1 / sqrt(3)), 0)\n\n    qc.h(1)\n    qc.cx(1, 2)\n\n\n    qc.cx(0, 1)\n\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 14, "result": "RE", "execution_time": "1194 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(1.231, 0)\n\n    qc.x(0)\n\n    qc.ch(0,1)\n    qc.x(1)\n    qc.cx(1, 2)\n\n\n    qc.ccx([0,1],2)\n\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 15, "result": "RE", "execution_time": "1165 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2*acos(1/sqrt(3)), 0)\n\n    qc.x(0)\n\n    qc.ch(0,1)\n    qc.x(1)\n    qc.cx(1, 2)\n\n\n    qc.ccx([0,1],2)\n\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A4F78A76F92B0", "submission_order": 16, "result": "RE", "execution_time": "1449 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2*acos(1/sqrt(3)), 0)\n\n    qc.x(0)\n\n    qc.ch(0,1)\n    qc.x(1)\n    qc.cx(1, 2)\n\n\n    qc.ccx([0,1],2)\n\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A5245D29BE20A", "submission_order": 1, "result": "WA", "execution_time": "1501 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    # Calculate angles\n    theta1 = 2 * math.acos(1 / math.sqrt(3))\n    theta2 = 2 * math.acos(1 / math.sqrt(2))\n\n    # Apply gates to create the W state\n    qc.u(theta1, 0, 0, 0)       # Apply R_y rotation on qubit 0\n    qc.cx(0, 1)                 # CNOT with qubit 0 as control and qubit 1 as target\n    qc.u(theta2, 0, 0, 1)       # Apply R_y rotation on qubit 1\n    qc.cx(1, 2)                 # CNOT with qubit 1 as control and qubit 2 as target\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A5245D29BE20A", "submission_order": 2, "result": "WA", "execution_time": "1487 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    # Calculate angle for first rotation\n    theta1 = 2 * math.acos(1 / math.sqrt(3))  # Rotation to create superposition with desired amplitudes\n\n    # Apply rotation on qubit 0 to create partial superposition\n    qc.ry(theta1, 0)\n    \n    # Apply CNOT gates to entangle qubits\n    qc.cx(0, 1)  # Control on qubit 0, target on qubit 1\n    qc.ry(2 * math.acos(1 / math.sqrt(2)), 1)  # Adjust the amplitude on qubit 1\n    qc.cx(1, 2)  # Control on qubit 1, target on qubit 2\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A5245D29BE20A", "submission_order": 3, "result": "AC", "execution_time": "1555 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    # Define rotation angles for controlled-Ry gates\n    theta1 = 2 * math.atan(math.sqrt(2))  # Angle to create superposition on first target\n    theta2 = 2 * math.atan(1)              # Angle to balance amplitudes between states\n\n    # Start with the initial state by flipping qubit 0\n    qc.x(0)\n\n    # Apply controlled-Ry rotation with qubit 0 as control and qubit 1 as target\n    qc.cry(theta1, 0, 1)\n    \n    # Apply CNOT with qubit 1 as control and qubit 0 as target to entangle states\n    qc.cx(1, 0)\n    \n    # Apply controlled-Ry with qubit 1 as control and qubit 2 as target\n    qc.cry(theta2, 1, 2)\n    \n    # Apply CNOT with qubit 2 as control and qubit 1 as target\n    qc.cx(2, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A561EDF4451B5", "submission_order": 1, "result": "RE", "execution_time": "1790 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    th = math.atan(math.sqrt(2))\n\n    qc.ry(th)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A561EDF4451B5", "submission_order": 2, "result": "RE", "execution_time": "1799 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    th = math.arctan(math.sqrt(2))\n\n    qc.ry(th)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A561EDF4451B5", "submission_order": 3, "result": "RE", "execution_time": "1776 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    th = math.atan(math.sqrt(2))\n\n    qc.ry(th)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A561EDF4451B5", "submission_order": 4, "result": "RE", "execution_time": "1824 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    th = math.artan(math.sqrt(2))\n\n    qc.ry(th, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A561EDF4451B5", "submission_order": 5, "result": "RE", "execution_time": "1792 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    th = math.artan(math.sqrt(2))\n\n    qc.ry(th, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A561EDF4451B5", "submission_order": 6, "result": "WA", "execution_time": "1879 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    th = math.atan(math.sqrt(2))\n\n    qc.ry(th, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A561EDF4451B5", "submission_order": 7, "result": "WA", "execution_time": "1890 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(2))\n\n    qc.ry(th, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A561EDF4451B5", "submission_order": 8, "result": "AC", "execution_time": "1878 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(2))\n\n    qc.ry(th, 0)\n    qc.ch(0, 1)\n    qc.x(2)\n    qc.cx(1, 0)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A56327EC88BBD", "submission_order": 1, "result": "AC", "execution_time": "1843 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    prob_amp = np.sqrt(1 / 3)\n    rot_ang = 2 * np.arccos(prob_amp)\n    qc.x(0)\n\n    for i in range(2):\n        comp_amp = np.sqrt(1 - i / 3)\n        rot_ang = 2 * np.arccos(prob_amp / (comp_amp))\n        qc.cry(rot_ang, i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A583E8FC9B550", "submission_order": 1, "result": "RE", "execution_time": "1440 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)  \n\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    \n    qc.ch(0, 1)\n\n    \n    qc.cx(1, 0)\n\n    qc.x(0)\n    qc.x(1)\n\n    qc.ccx(0,1,2)\n\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A583E8FC9B550", "submission_order": 2, "result": "AC", "execution_time": "1517 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)  \n\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    \n    qc.ch(0, 1)\n\n    \n    qc.cx(1, 0)\n\n    qc.x(0)\n    qc.x(1)\n\n    qc.ccx(0,1,2)\n\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A593B3D858E9A", "submission_order": 1, "result": "AC", "execution_time": "1600 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.ry(-math.asin(1/3), 0)\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.ch(1, 2)\n    qc.cx(2, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A5AE611BE6789", "submission_order": 1, "result": "AC", "execution_time": "1333 ms", "memory": "155 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\ndef F_gate(circ,i,j,n,k) :\n  theta = np.arccos(np.sqrt(1/(n-k+1)))\n  circ.ry(-theta,j)       \n  circ.cz(i,j)\n  circ.ry(theta,j)\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.x(2)\n    F_gate(qc,2,1,3,1) \n    F_gate(qc,1,0,3,2)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A5EAE83783718", "submission_order": 1, "result": "WA", "execution_time": "1510 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.x(1)\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(1)\n    qc.cx(1,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A63343A0194AC", "submission_order": 1, "result": "WA", "execution_time": "1468 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n\n    qc.cx(0,1)\n    qc.x(2)\n    qc.ccx(0,1,2)\n    qc.cx(0,1)\n    qc.x(2)\n\n    qc.x(1)\n    qc.x(2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A63343A0194AC", "submission_order": 2, "result": "WA", "execution_time": "1436 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n\n    qc.cx(0,1)\n    qc.cx(0,2)\n    \n    \n    qc.x(1) \n    qc.x(2)\n\n    \n    qc.ccx(1,2,0)\n    \n    qc.x(1)\n    qc.x(0)\n    qc.x(2)\n\n    qc.h(0)\n    qc.h(1)\n    qc.h(2)\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A63343A0194AC", "submission_order": 3, "result": "WA", "execution_time": "1448 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    \n    qc.h(2)\n    qc.cx(2, 1)\n    qc.cx(2, 0)\n    qc.x(1)\n    qc.x(0)\n    qc.barrier()\n\n\n    qc.h(2)\n    qc.cx(2, 1)\n    qc.cx(2, 0)\n    qc.h(2)\n    qc.barrier()\n\n    qc.x(2)\n    qc.cx(1, 0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A63343A0194AC", "submission_order": 4, "result": "WA", "execution_time": "1454 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(2)  \n    qc.cx(2, 1)  \n    qc.cx(2, 0)  \n    qc.x(2)\n    qc.h(2)\n    qc.ccx(1, 0, 2)\n    qc.h(2)\n    qc.x(2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A63343A0194AC", "submission_order": 5, "result": "WA", "execution_time": "1415 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)  \n    qc.t(0)  \n    qc.cx(0, 1)  \n    qc.cx(0, 2)  \n    qc.tdg(0)  \n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A63343A0194AC", "submission_order": 6, "result": "AC", "execution_time": "1334 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * np.arccos(1 / np.sqrt(3))\n    qc.ry(theta, 0)\n    h_gate = HGate()\n    ch_gate = h_gate.control(1)\n    qc.append(ch_gate, [0, 1])\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A6662CE07EF0C", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n      theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A6662CE07EF0C", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n      theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x()\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A6662CE07EF0C", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n      theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A6662CE07EF0C", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n      theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A6662CE07EF0C", "submission_order": 5, "result": "AC", "execution_time": "1592 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A678E2D48690D", "submission_order": 1, "result": "AC", "execution_time": "1653 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    qc.x(0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A690AF23AD126", "submission_order": 1, "result": "RE", "execution_time": "1469 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))) \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n    qc.cx(1, 2)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A690AF23AD126", "submission_order": 2, "result": "WA", "execution_time": "1544 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))) \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n    qc.cx(1, 2)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A690AF23AD126", "submission_order": 3, "result": "WA", "execution_time": "1645 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))) \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n    qc.cx(1, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A690AF23AD126", "submission_order": 4, "result": "WA", "execution_time": "1553 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))) \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(0, 1)\n    qc.cx(1, 2)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A6A6548F36D44", "submission_order": 1, "result": "WA", "execution_time": "1508 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.ccx(0, 1, 2)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A6A6548F36D44", "submission_order": 2, "result": "RE", "execution_time": "1546 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.u(2 * math.acos(1 / math.sqrt(3)), 0, 0, 0)  # 量子ビット 0 に U を適用\n    qc.cx(0, 1)  # 制御NOTでビット 1 と 0 をエンタングル\n    qc.cx(0, 2)  # 制御NOTでビット 2 と 0 をエンタングル\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A70B2E0DB5D26", "submission_order": 1, "result": "AC", "execution_time": "1434 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.x(2)\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 2)\n    qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7439B1BEDC99", "submission_order": 1, "result": "WA", "execution_time": "1770 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    t = 2*math.acos(math.sqrt(2/3))\n    qc.ry(t, 1)\n    qc.cx(1,0)\n    qc.ch(1,2)\n    qc.cx(2,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A754D7F3D836D", "submission_order": 1, "result": "AC", "execution_time": "1538 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nimport numpy\n\ndef solve() -> QuantumCircuit:\n    n = 3\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(n - 1):\n        theta = 2 * numpy.arccos(math.sqrt(1/(n - i)))\n        qc.cry(theta, i, i + 1)\n    \n    for i in range(n - 1):\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as m\nfrom qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.UnitaryGate((1/m.sqrt(3))matrix, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as m\nfrom qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.UnitaryGate((1/m.sqrt(3))*matrix, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 3, "result": "RE", "execution_time": "1435 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as m\n#from qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.UnitaryGate((1/m.sqrt(3))*matrix, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 4, "result": "RE", "execution_time": "1618 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as m\n#from qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.UnitaryGate((1/m.sqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 5, "result": "RE", "execution_time": "1720 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as m\n#from qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.UnitaryGate((1/sqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as m\nfrom qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.UnitaryGate((1/msqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 7, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as m\nfrom qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.UnitaryGate((1/sqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 8, "result": "RE", "execution_time": "1622 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\n#import math as m\n#from qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.unitary((1/sqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 9, "result": "RE", "execution_time": "1617 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as math\n#from qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.unitary((1/math.sqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 10, "result": "RE", "execution_time": "1425 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as math\n#from qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,1],\n       [0,0,0,0],\n       [0,0,0,0],\n       [0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.unitary((1/math.sqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 11, "result": "RE", "execution_time": "1471 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as math\n#from qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,1,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.unitary((1/math.sqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 12, "result": "RE", "execution_time": "1507 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as math\n#from qiskit.circuit.library import UnitaryGate\n\nmat = [[0,1,1,0,0,0,0,1],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0],\n       [0,0,0,0,0,0,0,0]] \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.unitary((1/math.sqrt(3))*mat, [0,1,2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A77C25D17A104", "submission_order": 13, "result": "RE", "execution_time": "1177 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n#import numpy as np\nimport math as math\n#from qiskit.circuit.library import UnitaryGate\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0) \n    qc.cx(0, 1) \n    qc.cx(0, 2)\n    qc.u1(-2 * np.arccos(1/np.sqrt(3)), 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A785C5B6B3991", "submission_order": 1, "result": "RE", "execution_time": "1559 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0,2)\n    qc.cx(0,1)\n    qc.cx(2,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A785C5B6B3991", "submission_order": 2, "result": "AC", "execution_time": "1245 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0,2)\n    qc.cx(0,1)\n    qc.cx(2,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A79127D1D6D04", "submission_order": 1, "result": "AC", "execution_time": "1731 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    prob_amp = np.sqrt(1 / 3)\n    rot_ang = 2 * np.arccos(prob_amp)\n    qc.x(0)\n\n    for i in range(2):\n        comp_amp = np.sqrt(1 - i / 3)\n        rot_ang = 2 * np.arccos(prob_amp / (comp_amp))\n        qc.cry(rot_ang, i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A794356B7F5B4", "submission_order": 1, "result": "AC", "execution_time": "1478 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(2))\n    qc.ry(theta, 0)\n    qc.ch(0,1)\n    qc.x(0)\n    qc.x(2)\n    qc.cx(0, 2)\n    qc.cx(1, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 1, "result": "WA", "execution_time": "1409 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 2, "result": "WA", "execution_time": "1840 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 3, "result": "RE", "execution_time": "1347 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * acos(sqrt(1/3))  \n    qc.ry(theta, 0)              \n    \n   \n    qc.cx(0, 1)                  \n    qc.cx(0, 2)   \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 4, "result": "RE", "execution_time": "1431 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.x(2)\n    qc.cx(0,1)\n    qc/cx(0,2) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 5, "result": "WA", "execution_time": "1362 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.x(1)\n    qc.x(2)\n    qc.cx(0,1)\n    qc.cx(0,2) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 6, "result": "WA", "execution_time": "1404 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n\n    qc.h(1)\n    qc.h(2)\n\n    qc.cx(1,2)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 7, "result": "WA", "execution_time": "1483 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 8, "result": "RE", "execution_time": "1386 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    angle = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(angle, 1)  # Rotate qubit 1\n    qc.ry(angle, 2)  # Rotate qubit 2\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 9, "result": "WA", "execution_time": "1464 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    angle = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(angle, 1)  # Rotate qubit 1\n    qc.ry(angle, 2)  # Rotate qubit 2\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 10, "result": "WA", "execution_time": "1600 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    qc.ccx(1,2,0)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 11, "result": "WA", "execution_time": "1534 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2* (1/math.sqrt(3)),0)\n\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 12, "result": "WA", "execution_time": "1642 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n\n    qc.cx(0,1)\n    qc.cx(0,2)\n\n    qc.rz(2 * (math.pi/3),1)\n    qc.rz(2 * (math.pi/3),2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 13, "result": "WA", "execution_time": "1307 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta_1 = 2 *np.arccos(1/ np.sqrt(3))\n    qc.ry(theta_1,0)\n\n    theta_2 = 2 * np.arccos(1/np.sqrt(2))\n    qc.cry(theta_2,0,1)\n\n    qc.cry(theta_2,0, 2)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 14, "result": "WA", "execution_time": "1194 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    theta_1 = 2 * np.arccos(1 / np.sqrt(3))\n    qc.ry(theta_1, 0)\n    theta_2 = 2 * np.arccos(1 / np.sqrt(2))\n    qc.cry(theta_2, 0, 1)\n    qc.cry(theta_2, 0, 2)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 15, "result": "WA", "execution_time": "1573 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    \n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n    qc.h(1)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 16, "result": "WA", "execution_time": "1676 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    \n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n    qc.h(1)\n    qc.h(2)\n    qc.ccx(1,2,0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A7E47F0E2B32C", "submission_order": 17, "result": "WA", "execution_time": "1772 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    \n    qc.h(0)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    \n    qc.p(math.pi / 3, 0)\n    qc.h(0)\n    \n    qc.p(-math.pi / 3, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A800AE79A3001", "submission_order": 1, "result": "WA", "execution_time": "1666 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(3)/3), 0)\n    qc.cry(math.acos(1/math.sqrt(2)), 0, 1)\n    qc.cx(1, 2)\n    qc.x(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A3", "user": "A800AE79A3001", "submission_order": 2, "result": "WA", "execution_time": "1459 ms", "memory": "154 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(3)/2), 0)\n    qc.cry(math.acos(1/math.sqrt(2)), 0, 1)\n    qc.cx(1, 2)\n    qc.x(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A3", "user": "A800AE79A3001", "submission_order": 3, "result": "WA", "execution_time": "1663 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(3)/2) * 2, 0)\n    qc.cry(math.acos(1/math.sqrt(2)) * 2, 0, 1)\n    qc.cx(1, 2)\n    qc.x(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A3", "user": "A800AE79A3001", "submission_order": 4, "result": "WA", "execution_time": "1418 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(2/3)) * 2, 0)\n    qc.cry(math.acos(1/math.sqrt(2)) * 2, 0, 1)\n    qc.cx(1, 2)\n    qc.x(0)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A3", "user": "A800AE79A3001", "submission_order": 5, "result": "WA", "execution_time": "1463 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(math.acos(math.sqrt(2/3)) * 2, 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cry(math.acos(math.sqrt(1/2)) * 2, 1, 2)\n    qc.cx(2, 1)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A3", "user": "A800AE79A3001", "submission_order": 6, "result": "AC", "execution_time": "1471 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(math.asin(math.sqrt(2/3)) * 2, 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cry(math.asin(math.sqrt(1/2)) * 2, 1, 2)\n    qc.cx(2, 1)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_A3", "user": "A818E296B1A17", "submission_order": 1, "result": "AC", "execution_time": "1568 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, acos, sqrt\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    \n    qc.ry(acos(sqrt(1/3)) * 2, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A3", "user": "A82220183435D", "submission_order": 1, "result": "WA", "execution_time": "1439 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    theta2 = 2 * np.arccos(1/np.sqrt(2))\n    \n    qc.ry(theta1, 0)\n    qc.cx(0, 1)\n    qc.ry(theta2, 1)\n    qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A827C1C055FAD", "submission_order": 1, "result": "AC", "execution_time": "1769 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(2*angle, 0)\n    qc.barrier()\n#1,2成分をBell状態の|01>+|10>にする\n    qc.h(1)\n    qc.cx(1,2)\n    qc.x(1)\n\n#Aliceが1のときBob, Charlieを|00>、入力状態に戻すために逆変換している（controlled x-gateはcx.()そのものである）\n    qc.cx(0,1)\n    qc.ccx(0,1,2)\n    qc.ch(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A83456261BBCA", "submission_order": 1, "result": "WA", "execution_time": "1593 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    qc.x(2)\n    qc.cx(2, 1)\n    qc.cx(0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A83456261BBCA", "submission_order": 2, "result": "AC", "execution_time": "1549 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    qc.x(2)\n    qc.cx(1, 2)\n    qc.cx(0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A85DE09C7FA90", "submission_order": 1, "result": "AC", "execution_time": "1484 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.x(0)\n    qc.cry(math.acos(1/3), 0, 2)\n    qc.cx(2, 0)\n\n    qc.cry(math.acos(0), 0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8697FFC8CF78", "submission_order": 1, "result": "RE", "execution_time": "1166 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(np.arccos(1/np.sqrt(3))*2, 0)\n    qc.cry(np.arccos(1/np.sqrt(2))*2, [0,1])\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8697FFC8CF78", "submission_order": 2, "result": "AC", "execution_time": "1439 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(np.arccos(1/np.sqrt(3))*2, 0)\n    qc.cry(np.arccos(1/np.sqrt(2))*2, 0, 1)\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8A8F7638616C", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.quantum_info import Statevector\n \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    \n    qc.ry(2 * np.arccos(np.sqrt(1/3)), 0)\n    qc.cry(2 * np.arccos(np.sqrt(1/2)), 0, 1)\n    # |001>の成分を作る\n    \n    qc.x(1)\n    qc.x(2)\n\n    qc.ccx(0, 1, 2)\n\n    qc.x(0)\n    qc.x(2)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8A8F7638616C", "submission_order": 2, "result": "AC", "execution_time": "1205 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n \n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    \n    qc.ry(2 * np.arccos(np.sqrt(1/3)), 0)\n    qc.cry(2 * np.arccos(np.sqrt(1/2)), 0, 1)\n    # |001>の成分を作る\n    \n    qc.x(1)\n    qc.x(2)\n\n    qc.ccx(0, 1, 2)\n\n    qc.x(0)\n    qc.x(2)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8C036DD9C8C9", "submission_order": 1, "result": "AC", "execution_time": "1667 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    import numpy as np\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8C1DCC3D7EE2", "submission_order": 1, "result": "AC", "execution_time": "1651 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    #000 -> 001\n    qc.x(0)\n    qc.x(1)\n    qc.mcx([0, 1], 2)\n    qc.x(0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8C3D38F3EDDC", "submission_order": 1, "result": "RE", "execution_time": "1557 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    q = QuantumRegister(n) \n\n    # Define a F_gate\n    def F_gate(circ,q,i,j,n,k) :\n        theta = np.arccos(np.sqrt(1/(n-k+1)))\n        circ.ry(-theta,q[j])       \n        circ.cz(q[i],q[j])\n        circ.ry(theta,q[j])\n        circ.barrier(q[i])\n    # Define the cxrv gate which uses reverse CNOT instead of CNOT\n    def  cxrv(circ,q,i,j) :\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.cx(q[j],q[i])\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.barrier(q[i],q[j])\n\n    \n    qc.x(q[2]) #start is |100>\n    F_gate(qc,q,2,1,3,1) # Applying F12\n    F_gate(qc,q,1,0,3,2) # Applying F23\n\n    if flag_qx2 : # option ibmqx2 \n        W_states.cx(q[1],q[2]) # cNOT 21\n        W_states.cx(q[0],q[1]) # cNOT 32\n        \n    else :        # option ibmqx4  \n        cxrv(W_states,q,1,2)\n        cxrv(W_states,q,0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8C3D38F3EDDC", "submission_order": 2, "result": "RE", "execution_time": "1188 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    q = QuantumRegister(n) \n\n    # Define a F_gate\n    def F_gate(circ,q,i,j,n,k) :\n        theta = np.arccos(np.sqrt(1/(n-k+1)))\n        circ.ry(-theta,q[j])       \n        circ.cz(q[i],q[j])\n        circ.ry(theta,q[j])\n        circ.barrier(q[i])\n    # Define the cxrv gate which uses reverse CNOT instead of CNOT\n    def  cxrv(circ,q,i,j) :\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.cx(q[j],q[i])\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.barrier(q[i],q[j])\n\n    \n    qc.x(q[2]) #start is |100>\n    F_gate(qc,q,2,1,3,1) # Applying F12\n    F_gate(qc,q,1,0,3,2) # Applying F23\n\n    if flag_qx2 : # option ibmqx2 \n        qc.cx(q[1],q[2]) # cNOT 21\n        qc.cx(q[0],q[1]) # cNOT 32\n        \n    else :        # option ibmqx4  \n        cxrv(qc,q,1,2)\n        cxrv(qc, q,0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8C3D38F3EDDC", "submission_order": 3, "result": "RE", "execution_time": "1711 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    q = QuantumRegister(3) \n\n    # Define a F_gate\n    def F_gate(circ,q,i,j,n,k) :\n        theta = np.arccos(np.sqrt(1/(n-k+1)))\n        circ.ry(-theta,q[j])       \n        circ.cz(q[i],q[j])\n        circ.ry(theta,q[j])\n        circ.barrier(q[i])\n    # Define the cxrv gate which uses reverse CNOT instead of CNOT\n    def  cxrv(circ,q,i,j) :\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.cx(q[j],q[i])\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.barrier(q[i],q[j])\n\n    \n    qc.x(q[2]) #start is |100>\n    F_gate(qc,q,2,1,3,1) # Applying F12\n    F_gate(qc,q,1,0,3,2) # Applying F23\n\n    if flag_qx2 : # option ibmqx2 \n        qc.cx(q[1],q[2]) # cNOT 21\n        qc.cx(q[0],q[1]) # cNOT 32\n        \n    else :        # option ibmqx4  \n        cxrv(qc,q,1,2)\n        cxrv(qc,q,0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8C3D38F3EDDC", "submission_order": 4, "result": "RE", "execution_time": "1498 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\n\ndef solve() -> QuantumCircuit:\n    # qc = QuantumCircuit(3)\n    # # Write your code here:\n    # q = QuantumRegister(3) \n\n    def F_gate(circ,q,i,j,n,k) :\n        theta = np.arccos(np.sqrt(1/(n-k+1)))\n        circ.ry(-theta,q[j])       \n        circ.cz(q[i],q[j])\n        circ.ry(theta,q[j])\n        circ.barrier(q[i])\n    # Define the cxrv gate which uses reverse CNOT instead of CNOT\n    def  cxrv(circ,q,i,j) :\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.cx(q[j],q[i])\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.barrier(q[i],q[j])\n\n    \n    # 3-qubit W state\n    flag_qx2 = True\n\n    n = 3\n    q_w = QuantumRegister(n) \n\n    W_states = QuantumCircuit(q_w) \n\n    W_states.x(q_w[2]) #start is |100>\n    F_gate(W_states,q_w,2,1,3,1) # Applying F12\n    F_gate(W_states,q_w,1,0,3,2) # Applying F23\n\n    if flag_qx2 : # option ibmqx2 \n        W_states.cx(q_w[1],q_w[2]) # cNOT 21\n        W_states.cx(q_w[0],q_w[1]) # cNOT 32\n        \n    else :        # option ibmqx4  \n        cxrv(W_states,q_w,1,2)\n        cxrv(W_states,q_w,0,1)\n    # print(W_states)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8C3D38F3EDDC", "submission_order": 5, "result": "RE", "execution_time": "1199 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # # Write your code here:\n    # q = QuantumRegister(3) \n\n    def F_gate(circ,q,i,j,n,k) :\n        theta = np.arccos(np.sqrt(1/(n-k+1)))\n        circ.ry(-theta,q[j])       \n        circ.cz(q[i],q[j])\n        circ.ry(theta,q[j])\n        circ.barrier(q[i])\n    # Define the cxrv gate which uses reverse CNOT instead of CNOT\n    def  cxrv(circ,q,i,j) :\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.cx(q[j],q[i])\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.barrier(q[i],q[j])\n\n    \n    # 3-qubit W state\n    flag_qx2 = True\n\n    n = 3\n    q_w = QuantumRegister(n) \n\n    qc = QuantumCircuit(q_w) \n\n    qc.x(q_w[2]) #start is |100>\n    F_gate(qc,q_w,2,1,3,1) # Applying F12\n    F_gate(qc,q_w,1,0,3,2) # Applying F23\n\n    if flag_qx2 : # option ibmqx2 \n        qc.cx(q_w[1],q_w[2]) # cNOT 21\n        qc.cx(q_w[0],q_w[1]) # cNOT 32\n        \n    else :        # option ibmqx4  \n        cxrv(qc,q_w,1,2)\n        cxrv(qc,q_w,0,1)\n    # print(qc)\n'''"}
{"problem": "QPC003_A3", "user": "A8C3D38F3EDDC", "submission_order": 6, "result": "AC", "execution_time": "1475 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # # Write your code here:\n    # q = QuantumRegister(3) \n\n    def F_gate(circ,q,i,j,n,k) :\n        theta = np.arccos(np.sqrt(1/(n-k+1)))\n        circ.ry(-theta,q[j])       \n        circ.cz(q[i],q[j])\n        circ.ry(theta,q[j])\n        circ.barrier(q[i])\n    # Define the cxrv gate which uses reverse CNOT instead of CNOT\n    def  cxrv(circ,q,i,j) :\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.cx(q[j],q[i])\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.barrier(q[i],q[j])\n\n    \n    # 3-qubit W state\n    flag_qx2 = True\n\n    n = 3\n    q_w = QuantumRegister(n) \n\n    qc = QuantumCircuit(q_w) \n\n    qc.x(q_w[2]) #start is |100>\n    F_gate(qc,q_w,2,1,3,1) # Applying F12\n    F_gate(qc,q_w,1,0,3,2) # Applying F23\n\n    if flag_qx2 : # option ibmqx2 \n        qc.cx(q_w[1],q_w[2]) # cNOT 21\n        qc.cx(q_w[0],q_w[1]) # cNOT 32\n        \n    else :        # option ibmqx4  \n        cxrv(qc,q_w,1,2)\n        cxrv(qc,q_w,0,1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8E41988847C3", "submission_order": 1, "result": "AC", "execution_time": "1917 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = math.atan(math.sqrt(2)) * 2\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(0, 2)\n    qc.x(0)\n    qc.cx(1, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8EFFC1926B6B", "submission_order": 1, "result": "WA", "execution_time": "1202 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.ccx(0, 1, 2)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8EFFC1926B6B", "submission_order": 2, "result": "AC", "execution_time": "1652 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(0)\n    qc.x(1)\n    qc.ccx(0, 1, 2)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A8F1919B28AB6", "submission_order": 1, "result": "AC", "execution_time": "1569 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3))) \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 2)\n    qc.cx(1, 2)\n    qc.x(2)\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A93D50E03B5C1", "submission_order": 1, "result": "AC", "execution_time": "1555 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    a = (1 / 3) ** 0.5\n    qc.ry(2 * math.acos(a), 0)\n    qc.ch(0, 1)\n    qc.x(2)\n    qc.cx(0, 2)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A952CA49E5F83", "submission_order": 1, "result": "WA", "execution_time": "1680 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.ry(acos(-1/3), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A952CA49E5F83", "submission_order": 2, "result": "WA", "execution_time": "1666 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.ry(acos(-1/3), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.x(0)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A952CA49E5F83", "submission_order": 3, "result": "WA", "execution_time": "1746 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.ry(acos(-1/3), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    \n    qc.cx(1, 2)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A952CA49E5F83", "submission_order": 4, "result": "WA", "execution_time": "1844 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.ry(acos(1/3), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    \n    qc.cx(1, 2)\n    qc.x(1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A952CA49E5F83", "submission_order": 5, "result": "AC", "execution_time": "1670 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.ry(acos(1/3), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n    \n    \n    qc.cx(1, 2)\n    qc.x(1)\n    qc.cx(0, 1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A96870D4BCC7F", "submission_order": 1, "result": "AC", "execution_time": "1438 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(3)\n\ttheta = 2 * acos(1 / sqrt(3))\n\tqc.x(0)\n\tqc.cry(theta, 0, 1)\n\tqc.ch(1, 0)\n\tqc.cz(0, 1)\n\tqc.x(0)\n\tqc.x(1)\n\tqc.ccx(0, 1, 2, ctrl_state = 0)\n\treturn qc\n'''"}
{"problem": "QPC003_A3", "user": "A96DE9CD41DF2", "submission_order": 1, "result": "WA", "execution_time": "1491 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.h(0)\n    qc.x(1)\n    qc.ch(0,2)\n    qc.cx(0,1)\n    qc.cx(2,0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "A96DE9CD41DF2", "submission_order": 2, "result": "AC", "execution_time": "1468 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 0)\n    qc.x(1)\n    qc.ch(0,2)\n    qc.cx(0,1)\n    qc.cx(2,0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    desired_state = Statevector([0, 1/3**0.5, 0, 0, 1/3**0.5, 0, 0, 1/3**0.5])\n    qc.initialize(desired_state, [0, 1, 2])\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 2, "result": "WA", "execution_time": "1474 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, UGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    \n    qc.h(0)\n    \n    qc.append(UGate(2 * (3 ** -0.5), 0, 0).control(1), [0, 1])\n    qc.append(UGate(2 * (3 ** -0.5), 0, 0).control(1), [0, 2])\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 3, "result": "WA", "execution_time": "1502 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import UGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n\n    qc.h(0)\n\n    amplitude = 2 * (1/3)**0.5  \n    qc.append(UGate(amplitude, 0, 0).control(1), [0, 1])  \n    qc.append(UGate(amplitude, 0, 0).control(1), [0, 2])  \n\n    qc.append(UGate(amplitude, 0, 0).control(1), [1, 2])  \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import  HGate, CCX\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n\n    qc.h(0)\n    qc.cx(0, 2)\n    qc.cx(0, 1)\n    qc.ccx(0, 1, 2)   \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import  HGate, CCX\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n\n    qc.h(0)\n    qc.cx(0, 2)\n    qc.cx(0, 1)\n    qc.ccx(0, 1, 2)   \n    angle = 2 * (-1.0 / 3)  \n    qc.rz(angle, 0)          \n    qc.rz(angle, 1)         \n    qc.rz(angle, 2) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CXGate, CCX\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.h(0)                 \n\n    qc.cx(0, 2)             \n    qc.cx(0, 1)             \n    qc.ccx(0, 1, 2)          \n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 7, "result": "WA", "execution_time": "1558 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CXGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.h(0)                 \n\n    qc.cx(0, 2)             \n    qc.cx(0, 1)             \n    qc.ccx(0, 1, 2)          \n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 8, "result": "WA", "execution_time": "1289 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CXGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.h(0)                 \n\n    qc.cx(0, 2)             \n    qc.cx(0, 1)             \n    qc.ccx(0, 1, 2)          \n    qc.h(0)\n    qc.h(1)\n    qc.h(2)\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AA3E5A62F2D1A", "submission_order": 9, "result": "WA", "execution_time": "1645 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    qc.h(0)                 \n\n    qc.cx(0, 2)             \n    qc.cx(0, 1)             \n    qc.ccx(0, 1, 2)          \n    qc.h(0)\n    qc.h(1)\n    qc.h(2)\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AABB2333DBF55", "submission_order": 1, "result": "WA", "execution_time": "1662 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(math.sqrt(2)), 0, 1)\n    qc.cx(0,1)\n    qc.cry(math.pi, 1, 2)\n    qc.cx(2,1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AABB2333DBF55", "submission_order": 2, "result": "WA", "execution_time": "1586 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(math.sqrt(2)), 0, 1)\n    qc.cx(0,1)\n    qc.cry(math.pi / 2, 1, 2)\n    qc.cx(2,1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AABB2333DBF55", "submission_order": 3, "result": "WA", "execution_time": "1665 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(math.sqrt(2)), 0, 1)\n    qc.cx(0,1)\n    qc.cry(math.pi / 2, 1, 2)\n    qc.cx(2,1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AABB2333DBF55", "submission_order": 4, "result": "AC", "execution_time": "1581 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(math.sqrt(2)), 0, 1)\n    qc.cx(1,0)\n    qc.cry(math.pi / 2, 1, 2)\n    qc.cx(2,1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 1, "result": "WA", "execution_time": "1239 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    qc.cx(2,0)\n    qc.cx(2,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 2, "result": "WA", "execution_time": "1680 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.h(0)\n    qc.x(1)\n    qc.cx(0,1)\n    qc.cx(1,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 3, "result": "RE", "execution_time": "1207 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0)\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 1)\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 2) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 4, "result": "WA", "execution_time": "1715 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0)\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 1)\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 2) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 5, "result": "WA", "execution_time": "1548 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0)\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 1)\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 2) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom math import arccos\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2 * arccos(1 / np.sqrt(3)), 0)\n    qc.ry(2 * arccos(1 / np.sqrt(3)), 1)\n    qc.ry(2 * arccos(1 / np.sqrt(3)), 2) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 7, "result": "WA", "execution_time": "1239 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.h(2)\n\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0)\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 1)\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 2) \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 8, "result": "WA", "execution_time": "1275 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.h(0)  # Hadamard on qubit 0\n    qc.cry(2 * np.arccos(1 / np.sqrt(3)), 0, 1)\n    qc.cry(2 * np.arccos(1 / np.sqrt(3)), 0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACC76A1A1E82", "submission_order": 9, "result": "WA", "execution_time": "2080 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.h(0)  # Hadamard on qubit 0\n    qc.ccx(0,1,2).inverse(True)\n    qc.ccx(0,2,1).inverse(True)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 1, "result": "RE", "execution_time": "1538 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.toffoli(0,1,2)\n    qc.toffoli(1,2,0)\n    qc.cx(2,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 2, "result": "WA", "execution_time": "1490 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ccx(0,1,2)\n    qc.ccx(1,2,0)\n    qc.cx(2,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 3, "result": "WA", "execution_time": "1594 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.ccx(0,1,2)\n    qc.h(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 4, "result": "WA", "execution_time": "1622 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(2) \n    qc.h(1)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,2)\n    qc.cx(0,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 5, "result": "RE", "execution_time": "1418 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0) \n    qc.cry(np.arctan(np.sqrt(2))*2, 0, 1)\n    qc.cx(1,0)\n    qc.cry(np.arctan(1)*2, 1,2)\n    qc.cx(2,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 6, "result": "RE", "execution_time": "1315 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc = QuantumCircuit(3)\n    qc.x(2) \n    qc.cry(np.arctan(np.sqrt(2))*2, 2, 1)\n    qc.cx(1,2)\n    qc.cry(np.arctan(1)*2, 1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 7, "result": "RE", "execution_time": "1635 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(2) \n    qc.cry(np.arctan(np.sqrt(2))*2, 2, 1)\n    qc.cx(1,2)\n    qc.cry(np.arctan(1)*2, 1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 8, "result": "RE", "execution_time": "1519 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0) \n    qc.cry(np.arctan(np.sqrt(2))*2, 0, 1)\n    qc.cx(1,0)\n    qc.cry(np.arctan(1)*2, 1,2)\n    qc.cx(2,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 9, "result": "RE", "execution_time": "1526 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0) \n    qc.cry(np.arctan(np.sqrt(2))*2, 0, 1)\n    qc.cx(1,0)\n    qc.cry(np.arctan(1)*2, 1, 2)\n    qc.cx(2,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 10, "result": "RE", "execution_time": "1482 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(np.arctan(np.sqrt(2))*2, 0, 1)\n    qc.cx(1, 0)\n    qc.cry(np.arctan(1)*2, 1, 2)\n    qc.cx(2, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 11, "result": "RE", "execution_time": "1573 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(np.arctan(np.sqrt(2))*2, 0, 1)\n    qc.cx(1, 0)\n    #qc.cry(np.arctan(1)*2, 1, 2)\n    qc.cry(np.pi/2, 1, 2)\n    qc.cx(2, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 12, "result": "RE", "execution_time": "1516 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(1.91, 0, 1)\n    qc.cx(1, 0)\n    #qc.cry(np.arctan(1)*2, 1, 2)\n    qc.cry(np.pi/2, 1, 2)\n    qc.cx(2, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AACF0D1970F3A", "submission_order": 13, "result": "AC", "execution_time": "1419 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(np.arctan(np.sqrt(2))*2, 0, 1)\n    #qc.cry(1.91, 0, 1)\n    qc.cx(1, 0)\n    qc.cry(np.arctan(1)*2, 1, 2)\n    #qc.cry(np.pi/2, 1, 2)\n    qc.cx(2, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AAE320D1BE5CC", "submission_order": 1, "result": "RE", "execution_time": "1726 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.x(0)\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 1)\n    qc.ch(1, 2)\n    qc.cx(1, 0)\n    qc.cx(2, 1)\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AAE320D1BE5CC", "submission_order": 2, "result": "AC", "execution_time": "1525 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.x(0)\n    theta = 2 * math.acos(1 / math.sqrt(3))\n    qc.ry(theta, 1)\n    qc.ch(1, 2)\n    qc.cx(1, 0)\n    qc.cx(2, 1)\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AB751F770FA1F", "submission_order": 1, "result": "AC", "execution_time": "1528 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(math.sqrt(2)),0,1)\n    qc.cx(1,0)\n    qc.cry(math.pi / 2,1,2)\n    qc.cx(2,1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABB6F65B44CDF", "submission_order": 1, "result": "WA", "execution_time": "2050 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    # Apply a Hadamard gate to the first qubit to create superposition\n    qc.h(0)\n\n    # Apply controlled rotations to create the desired amplitudes\n    # We will use a combination of RY gates to adjust the amplitudes\n    theta = math.acos(1 / math.sqrt(3))  # This is the angle for the RY gate\n\n    # Apply RY gates to the second and third qubits\n    qc.ry(2 * theta, 1)  # Apply RY to the second qubit\n    qc.ry(2 * theta, 2)  # Apply RY to the third qubit\n\n    # Apply CNOT gates to entangle the qubits\n    qc.cx(0, 1)  # Control on qubit 0, target qubit 1\n    qc.cx(0, 2)  # Control on qubit 0, target qubit 2\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABB6F65B44CDF", "submission_order": 2, "result": "WA", "execution_time": "1893 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Step 1: Ry(2*arccos(1/√3)) on qubit 0\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    qc.ry(theta1, 0)\n    # Step 2: CNOT from qubit 0 to qubit 1\n    qc.cx(0, 1)\n    # Step 3: Ry(π/2) on qubit 1\n    qc.ry(np.pi/2, 1)\n    # Step 4: CNOT from qubit 1 to qubit 2\n    qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABB6F65B44CDF", "submission_order": 3, "result": "WA", "execution_time": "1994 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Step 1: Ry(2*arccos(1/√3)) on qubit 0\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    qc.x(0)\n    qc.ry(theta1, 0)\n    # Step 2: CNOT from qubit 0 to qubit 1\n    qc.cx(0, 1)\n    # Step 3: Ry(π/2) on qubit 1\n    qc.ry(np.pi/2, 1)\n    # Step 4: CNOT from qubit 1 to qubit 2\n    qc.cx(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABB6F65B44CDF", "submission_order": 4, "result": "WA", "execution_time": "1967 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Step 1: Ry(2*arccos(1/√3)) on qubit 0\n    theta1 = 2 * np.arccos(1/np.sqrt(3))\n    \n    qc.ry(theta1, 0)\n    # Step 2: CNOT from qubit 0 to qubit 1\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    # Step 3: Ry(π/2) on qubit 1\n    qc.ry(np.pi/2, 1)\n    # Step 4: CNOT from qubit 1 to qubit 2\n    qc.x(1)\n    qc.cx(1, 2)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABB6F65B44CDF", "submission_order": 5, "result": "RE", "execution_time": "1790 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Step 1: Ry(2*arccos(1/√3)) on qubit 0\n    theta1 = 2 * np.arctan(np.sqrt(2))\n    qc.ry(theta1, 0)\n    # Step 2: CNOT from qubit 0 to qubit 1\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    # Step 3: Ry(π/2) on qubit 1\n    qc.ry(np.pi/2, 1)\n    # Step 4: CNOT from qubit 1 to qubit 2\n    qc.x(1)\n    qc.cx(1, 2)\n    qc.x()\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABB6F65B44CDF", "submission_order": 6, "result": "WA", "execution_time": "2078 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    \n    # Apply Hadamard to the first qubit\n    qc.h(0)\n    \n    # Apply controlled rotations to create the superposition\n    qc.cx(0, 1)  # Control from qubit 0 to qubit 1\n    qc.cx(0, 2)  # Control from qubit 0 to qubit 2\n    \n    # Normalize the state by applying a rotation\n    qc.rz(math.acos(1/3), 0)  # Rotate to adjust the amplitude\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABC25DCFD8206", "submission_order": 1, "result": "WA", "execution_time": "1786 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2 * acos(sqrt(1/3)), 0) #Rotar\n    qc.cx(0, 1) #ENtrelazar\n    qc.cx(1, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABC25DCFD8206", "submission_order": 2, "result": "WA", "execution_time": "1602 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, sqrt\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0) #Superposicion\n    # Aplicamos CNOT\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ABC25DCFD8206", "submission_order": 3, "result": "AC", "execution_time": "1338 ms", "memory": "154 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta1 = 2 * math.atan(math.sqrt(2))\n    theta2 = 2 * math.atan(1)\n \n    qc.x(0)\n    qc.cry(theta1, 0, 1)\n    qc.cx(1, 0)\n    qc.cry(theta2, 1, 2)\n    qc.cx(2, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AC073CC56B860", "submission_order": 1, "result": "WA", "execution_time": "1239 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = math.asin(1.0 / math.sqrt(3.0))\n    qc.ry(2.0 * theta, 1)\n    qc.x(1)\n    qc.ch(1, 2)\n    qc.x(1)\n\n    qc.x(1)\n    qc.x(2)\n\n    qc.cx([1, 2], 0)\n    qc.x(1)\n    qc.x(2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AC073CC56B860", "submission_order": 2, "result": "AC", "execution_time": "1450 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = math.asin(1.0 / math.sqrt(3.0))\n    qc.ry(2.0 * theta, 1)\n    qc.x(1)\n    qc.ch(1, 2)\n    qc.x(1)\n\n    qc.x([1, 2])\n    qc.ccx(1, 2, 0)\n    qc.x([1, 2])\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AC226FA23314C", "submission_order": 1, "result": "AC", "execution_time": "1693 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.ry(2 * math.acos(math.sqrt(2)/math.sqrt(3)), 0)\n    qc.x(0)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    qc.cx(0, 2)\n    qc.x(0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AC521027F3134", "submission_order": 1, "result": "AC", "execution_time": "1513 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta, 1)\n    qc.ch(1,2)\n    qc.x(0)\n    qc.cx(1,0)\n    qc.cx(2,1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AC84D408C2A1F", "submission_order": 1, "result": "RE", "execution_time": "1363 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * acos(1 / (3**0.5))\n\n    qc.ry(theta, 0)\n    qc.cry(pi / 2, 0, 1)\n    qc.mcx([0, 1], 2)\n    qc.x([0, 1])\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AC84D408C2A1F", "submission_order": 2, "result": "AC", "execution_time": "1571 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, pi\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * acos(1 / (3**0.5))\n\n    qc.ry(theta, 0)\n    qc.cry(pi / 2, 0, 1)\n    qc.mcx([0, 1], 2)\n    qc.x([0, 1])\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ACA5A08B3796C", "submission_order": 1, "result": "WA", "execution_time": "1652 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.ry(4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3))), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ACA5A08B3796C", "submission_order": 2, "result": "AC", "execution_time": "1424 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.ry(4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3))), 2)\n    qc.ch(2, 1)\n    qc.cx(2, 0)\n    qc.cx(1, 0)\n    qc.x(2)\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ACB299D2BBE42", "submission_order": 1, "result": "AC", "execution_time": "1560 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.x(1)\n    qc.cx(0, 1)\n    qc.ch(0, 2)\n    qc.cx(2, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 1, "result": "RE", "execution_time": "1197 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(0)\n    qc.x(1)\n    qc.mcx([0, 1], 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 2, "result": "RE", "execution_time": "1668 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(0)\n    qc.x(1)\n    qc.mcx([0, 1], 2)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 3, "result": "RE", "execution_time": "1533 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(0)\n    qc.x(1)\n    qc.ccx([0, 1], 2)\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 4, "result": "RE", "execution_time": "1510 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 2 * math.acos(1/ math.sqrt(3))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 5, "result": "RE", "execution_time": "1494 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.ccx(0, 1, 2)\n    qc.x([0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 6, "result": "RE", "execution_time": "1753 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.ccx(0, 1, 2)\n    qc.x([0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 7, "result": "RE", "execution_time": "1407 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.toffoli(0, 1, 2)\n    qc.x([0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 8, "result": "RE", "execution_time": "1223 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.toffoli(0, 1, 2)\n    qc.x([0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 9, "result": "RE", "execution_time": "1382 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    # qc.ccx(0, 1, 2)\n    qc.x([0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 10, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)s\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.ccx(0, 1, 2)\n    qc.x([0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,ControlledGate\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)s\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.ccx(0, 1, 2)\n    qc.x([0, 1])\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 12, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,ControlledGate\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 13, "result": "WA", "execution_time": "1477 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n \n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 14, "result": "WA", "execution_time": "1557 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 15, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)s\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.ccx(0, 1, 2)\n    qc.x([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 16, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)s\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 17, "result": "WA", "execution_time": "1329 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 18, "result": "WA", "execution_time": "1729 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    # qc.ccx(0, 1, 2)\n    # qc.x([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 19, "result": "WA", "execution_time": "1661 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.ccx(0, 1, 2)\n    # qc.x([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD3E1F5956181", "submission_order": 20, "result": "AC", "execution_time": "1936 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x([0, 1])\n    qc.ccx(0, 1, 2)\n    qc.x([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD655BEF5C7C7", "submission_order": 1, "result": "AC", "execution_time": "1749 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef make_three_uniform() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.h(0)\n    qc.ry(math.asin(1 / 3), 0)\n    qc.ch(0, 1)\n    qc.x(0)\n    return qc\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.compose(make_three_uniform(), inplace=True)\n    qc.x([0, 1])\n    qc.ccx(0, 1, 2)\n    qc.x([0, 1])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD725D3B4C361", "submission_order": 1, "result": "AC", "execution_time": "1280 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, HGate, CXGate, MCPhaseGate \nimport math\n\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.ry(2 * math.acos(1/math.sqrt(3)), 0)\n    qc.ch([0], [1])\n    qc.cx([1], [2])\n    qc.cx([0], [1])\n    qc.x([0])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD851C61715C7", "submission_order": 1, "result": "RE", "execution_time": "1254 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD851C61715C7", "submission_order": 2, "result": "WA", "execution_time": "1756 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.ch(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD851C61715C7", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD851C61715C7", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AD851C61715C7", "submission_order": 5, "result": "AC", "execution_time": "1827 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADB1926DEEC5E", "submission_order": 1, "result": "RE", "execution_time": "1414 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    # Definir el vector de estado deseado\n    desired_state = [0]*8  # Hay 2^3 = 8 estados base computacionales\n    desired_state[1] = 1/sqrt(3)  # Estado |001⟩\n    desired_state[2] = 1/sqrt(3)  # Estado |010⟩\n    desired_state[4] = 1/sqrt(3)  # Estado |100⟩\n\n    # Inicializar los qubits al estado deseado\n    qc.initialize(desired_state, [0, 1, 2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADB1926DEEC5E", "submission_order": 2, "result": "UGE", "execution_time": "1712 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    # Definir el vector de estado deseado\n    desired_state = [0]*8  # Hay 2^3 = 8 estados base computacionales\n    desired_state[1] = 1/sqrt(3)  # Estado |001⟩\n    desired_state[2] = 1/sqrt(3)  # Estado |010⟩\n    desired_state[4] = 1/sqrt(3)  # Estado |100⟩\n\n    # Inicializar los qubits al estado deseado\n    qc.initialize(desired_state, [0, 1, 2])\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADB1926DEEC5E", "submission_order": 3, "result": "AC", "execution_time": "1623 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math as math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(3)), 0)\n    qc.ch(0, 1)\n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADC8D4EC2AE9B", "submission_order": 1, "result": "RE", "execution_time": "1146 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * np.arcsin(np.sqrt(1/3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADC8D4EC2AE9B", "submission_order": 2, "result": "WA", "execution_time": "1525 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * np.arcsin(np.sqrt(1/3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADC8D4EC2AE9B", "submission_order": 3, "result": "WA", "execution_time": "1924 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 2 * math.asin(math.sqrt(1/3))\n    qc.ry(theta, 0)\n\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADC8D4EC2AE9B", "submission_order": 4, "result": "WA", "execution_time": "1436 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADC8D4EC2AE9B", "submission_order": 5, "result": "RE", "execution_time": "1479 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    theta = 2 * math.asin(math.sqrt(1/3))  # 角度 θ = 2 * arcsin(√(1/3))\n    qc.ry(theta, 0)  # 量子ビット0に対してRyゲートを適用\n\n    # 量子ビット0が1のときに量子ビット1と2をエンタングルメント\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADC8D4EC2AE9B", "submission_order": 6, "result": "UGE", "execution_time": "1640 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.initialize([0, sqrt(1/3), sqrt(1/3), 0, sqrt(1/3), 0, 0, 0], [0, 1, 2])\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADC8D4EC2AE9B", "submission_order": 7, "result": "RE", "execution_time": "1161 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.h(0)\n\n    # 位相を調整するために、第0量子ビットにRZゲートを適用\n    qc.rz(2 * pi / 3, 0)\n\n    # それぞれの状態に重ね合わせを作るためにCNOTを使う\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADCA9595615E6", "submission_order": 1, "result": "WA", "execution_time": "1695 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(2)\n    qc.cx(1,2)\n    qc.cx(0,2)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADCA9595615E6", "submission_order": 2, "result": "WA", "execution_time": "1665 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADCA9595615E6", "submission_order": 3, "result": "RE", "execution_time": "1609 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(2)\n    qc.mcx((1,2),0)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADCA9595615E6", "submission_order": 4, "result": "WA", "execution_time": "1441 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(2)\n    qc.mcp(math.pi,list(range(1,3)),0)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADCA9595615E6", "submission_order": 5, "result": "WA", "execution_time": "1586 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.x(2)\n    qc.mcx(list(range(1,3)),0)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADCA9595615E6", "submission_order": 6, "result": "AC", "execution_time": "1639 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    t =np.arccos(1/np.sqrt(3))\n    qc.ry(t*2,0)\n    tt =np.arccos(1/np.sqrt(2))\n    qc.cry(tt*2,0,1)\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADE0159047CF6", "submission_order": 1, "result": "AC", "execution_time": "1605 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n#from qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,2)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n\n#if __name__ == \"__main__\":\n#    qc = solve()\n#    print(Statevector(qc))\n'''"}
{"problem": "QPC003_A3", "user": "ADF5770784D64", "submission_order": 1, "result": "RE", "execution_time": "1450 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(0.9553166181245092*2)[0].cry(0.7853981633974484*2)[0,1].x[2].cx[0, 2].cx[1, 0]\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADF5770784D64", "submission_order": 2, "result": "RE", "execution_time": "1383 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(0.9553166181245092*2)[0]\n    qc.cry(0.7853981633974484*2)[0,1]\n    qc.x[2]\n    qc.cx[0, 2]\n    qc.cx[1, 0]\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADF5770784D64", "submission_order": 3, "result": "RE", "execution_time": "1827 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(0.9553166181245092*2)[0]\n    qc.cry(0.7853981633974484*2)[0,1]\n    qc.x[2]\n    qc.cx[0, 2]\n    qc.cx[1, 0]\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADF5770784D64", "submission_order": 4, "result": "RE", "execution_time": "1827 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(0.9553166181245092*2)[0]\n    qc.cry(0.7853981633974484*2)[0,1]\n    qc.x[2]\n    qc.cx[0, 2]\n    qc.cx[1, 0]\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADF5770784D64", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit,math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(0.9553166181245092*2)[0]\n    qc.cry(0.7853981633974484*2)[0,1]\n    qc.x[2]\n    qc.cx[0, 2]\n    qc.cx[1, 0]\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "ADF5770784D64", "submission_order": 6, "result": "AC", "execution_time": "1350 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(0.9553166181245092*2,0)\n    qc.cry(0.7853981633974484*2,0,1)\n    qc.x(2)\n    qc.cx(0, 2)\n    qc.cx(1, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE1457FEEEF99", "submission_order": 1, "result": "AC", "execution_time": "1963 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(2))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.x(1)\n    qc.ch(0, 2)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE15DF7B639B0", "submission_order": 1, "result": "WA", "execution_time": "1373 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0, 2)\n    qc.cx(1, 2)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE263F720CDB2", "submission_order": 1, "result": "RE", "execution_time": "1591 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(3)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE263F720CDB2", "submission_order": 2, "result": "RE", "execution_time": "1470 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE263F720CDB2", "submission_order": 3, "result": "WA", "execution_time": "1532 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE263F720CDB2", "submission_order": 4, "result": "AC", "execution_time": "1637 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.cx(1,2)\n    qc.x(2)\n    qc.cx(0,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE38E1B0F4EFA", "submission_order": 1, "result": "AC", "execution_time": "1220 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    qc.r(2*math.acos(1.0/math.sqrt(3.0)), math.pi/2, 0)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.ccx(0, 1, 2)\n    qc.x(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE3E1B7F5BE86", "submission_order": 1, "result": "RE", "execution_time": "1917 ms", "memory": "154 MiB", "code": "'''python\nfrom math import acos, pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = acos((2 / 3) ** 0.5)\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    phi = pi / 2\n    qc.cry(phi, 0, 2)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE3E1B7F5BE86", "submission_order": 2, "result": "WA", "execution_time": "1579 ms", "memory": "155 MiB", "code": "'''python\nfrom math import acos, pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = acos((2 / 3) ** 0.5)\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    phi = pi / 2\n    qc.cry(phi, 0, 2)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE3E1B7F5BE86", "submission_order": 3, "result": "WA", "execution_time": "1403 ms", "memory": "155 MiB", "code": "'''python\nfrom math import acos, pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * acos((2 / 3) ** 0.5)\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    phi = pi / 2\n    qc.cry(phi, 0, 2)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE3E1B7F5BE86", "submission_order": 4, "result": "AC", "execution_time": "1425 ms", "memory": "154 MiB", "code": "'''python\nfrom math import acos, pi\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2 * acos((2 / 3) ** 0.5)\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    phi = pi / 2\n    qc.cry(phi, 0, 2)\n    qc.cx(2, 0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE5CC375D2FE4", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    \n    a = np.array([0,1,1,0,1,0,0,0])\n    a = a/(sum(abs(a)**2)**0.5)\n    qc.initialize(a,range(0,3))\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE604173689AD", "submission_order": 1, "result": "RE", "execution_time": "1734 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i == 0:\n            qc.h(i)\n        else:\n            qc.append(HGate().control(i), list(range(i+1)))\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE9B0F3B959C7", "submission_order": 1, "result": "RE", "execution_time": "1311 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2*np.arccos(1/np.sqrt(3))\n    qc.ry(theta, 0)\n    h_gate = HGate()\n    ch_gate = h_gate.control(1)\n    qc.append(ch_gate, [0, 1]) \n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE9B0F3B959C7", "submission_order": 2, "result": "RE", "execution_time": "1580 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2*np.arccos(1/np.sqrt(3))\n    qc.ry(theta, 0)\n    h_gate = qiskit.circuit.library.HGate()\n    ch_gate = h_gate.control(1)\n    qc.append(ch_gate, [0, 1]) \n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AE9B0F3B959C7", "submission_order": 3, "result": "AC", "execution_time": "1491 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 2*np.arccos(1/np.sqrt(3))\n    qc.ry(theta, 0)\n    h_gate = HGate()\n    ch_gate = h_gate.control(1)\n    qc.append(ch_gate, [0, 1]) \n    qc.cx(1, 2)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF0B1E54EACD3", "submission_order": 1, "result": "RE", "execution_time": "1583 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(2)\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n\n \n    qc.ry(theta, 1)\n\n    qc.ch(1,0)\n\n    qc.cx(1,2)\n    qc.cx(0,1)\n\n\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF0B1E54EACD3", "submission_order": 2, "result": "RE", "execution_time": "1374 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(2)\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n\n \n    qc.ry(theta, 1)\n\n    qc.ch(1,0)\n\n    qc.cx(1,2)\n    qc.cx(0,)\n\n\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF0B1E54EACD3", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(2)\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n\n \n    qc.ry(theta, 1)\n\n    qc.ch(1,0)\n\n    qc.cx(1,2)\n    qc.cx(0,1)\n\n\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF0B1E54EACD3", "submission_order": 4, "result": "AC", "execution_time": "1506 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(2)\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n\n \n    qc.ry(theta, 1)\n\n    qc.ch(1,0)\n\n    qc.cx(1,2)\n    qc.cx(0,1)\n\n\n\n\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF117AA379279", "submission_order": 1, "result": "AC", "execution_time": "1510 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    n = 3\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(math.asin(1/math.sqrt(n))*2, 0)\n    for i in range(1, n):\n        for j in range(i):\n            qc.x(j)\n        qc.append(RYGate(math.asin(1/math.sqrt(n-i))*2).control(i), range(i+1))\n        for j in range(i):\n            qc.x(j)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A3", "user": "AF1C8A6249533", "submission_order": 1, "result": "AC", "execution_time": "1922 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\n\ndef solve() -> QuantumCircuit:\n  qc = QuantumCircuit(3)\n  qc.ry(math.acos(-1/3), 0)\n  qc.swap(0, 1)\n  qc.cx(1,0)\n  qc.ch(0,2)\n  qc.x(0)\n  qc.cx(2, 1)\n\n\n  return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF374CEE09EFF", "submission_order": 1, "result": "RE", "execution_time": "1408 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.ch(1, 2)\n    qc.cx(2, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF374CEE09EFF", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nimport matplotlib.pyplot as plt\nfrom qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.ch(1, 2)\n    qc.cx(2, 1)\n    qc.cx(2, 0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF374CEE09EFF", "submission_order": 3, "result": "WA", "execution_time": "1618 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.ch(1, 2)\n    qc.cx(2, 1)\n    qc.cx(2, 0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF374CEE09EFF", "submission_order": 4, "result": "AC", "execution_time": "1455 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.x(0)\n    qc.ry(theta, 1)\n    qc.ch(1, 2)\n    qc.cx(2, 1)\n    qc.cx(2, 0)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF3F4337FEDC2", "submission_order": 1, "result": "WA", "execution_time": "1679 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.ccx(0,1,2)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF3F4337FEDC2", "submission_order": 2, "result": "RE", "execution_time": "1618 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.ccx(0,1,2)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF3F4337FEDC2", "submission_order": 3, "result": "AC", "execution_time": "1274 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.ccx(0,1,2)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF661A5260322", "submission_order": 1, "result": "RE", "execution_time": "1479 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF661A5260322", "submission_order": 2, "result": "AC", "execution_time": "1480 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n \n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 1, "result": "RE", "execution_time": "1494 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(0, np.acos(p))\n    qc.cx(0,1)\n    qc.x(0)\n    qc.x(2)\n    qc.cx(1,2)\n    qc.x(2)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 2, "result": "WA", "execution_time": "1518 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(np.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.x(2)\n    qc.cx(1,2)\n    qc.x(2)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 3, "result": "WA", "execution_time": "1392 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(np.cos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.x(2)\n    qc.cx(1,2)\n    qc.x(2)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 4, "result": "WA", "execution_time": "1515 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(np.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 5, "result": "WA", "execution_time": "1424 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(-np.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 6, "result": "WA", "execution_time": "1600 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = -1/3\n    qc.ry(np.acos(p),0)\n    qc.cx(0,1)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 7, "result": "WA", "execution_time": "1602 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = -1/3\n    qc.ry(math.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 8, "result": "WA", "execution_time": "1498 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(math.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 9, "result": "WA", "execution_time": "1418 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(2*math.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 10, "result": "WA", "execution_time": "1402 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(2*math.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 11, "result": "WA", "execution_time": "1444 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = 1/3\n    qc.ry(math.acos(2*p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 12, "result": "WA", "execution_time": "1421 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = -1/3\n    qc.ry(math.acos(2*p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 13, "result": "WA", "execution_time": "1478 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = -1/3\n    qc.ry(2*math.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 14, "result": "WA", "execution_time": "1436 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = math.sqrt(2/3)\n    qc.ry(2*math.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 15, "result": "WA", "execution_time": "1511 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = math.sqrt(2/3)\n    qc.ry(2*math.acos(p),0)\n    qc.cx(0,1)\n    qc.x(0)\n\n    qc.ch(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 16, "result": "WA", "execution_time": "1585 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = math.sqrt(1/3)\n    qc.ry(2 * math.acos(p), 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.ch(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 17, "result": "WA", "execution_time": "1582 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = math.sqrt(1/3)\n    qc.ry( math.acos(p), 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.ch(1, 2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF6F876325EAA", "submission_order": 18, "result": "AC", "execution_time": "1444 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    p = math.sqrt(1/3)\n    qc.ry(2*math.acos(p), 0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.ch(1, 2)\n    qc.cx(2, 1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AF8CA644E3CA1", "submission_order": 1, "result": "AC", "execution_time": "1323 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n\n    # Write your code here:\n    root_3 = np.sqrt(3)\n    phi = 2 * np.arccos(1/root_3)\n\n    qc.ry(phi, 0)\n    qc.ch(0, 1)\n    qc.cx(1,2)\n    qc.cx(0,1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFA6F52B0D89C", "submission_order": 1, "result": "AC", "execution_time": "1488 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import atan, sqrt\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * atan(sqrt(6) / (3 + sqrt(3)))\n    qc.x(0)\n    qc.ry(theta, 1)\n    qc.ch(1, 2)\n    qc.cx(1, 0)\n    qc.cx(2, 1)\n \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFADD5DA171D1", "submission_order": 1, "result": "RE", "execution_time": "1507 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    # 量子ビット0にアダマールゲートを適用\n    qc.h(0)\n    \n    # 量子ビット1に制御NOTゲートを適用\n    qc.cx(0, 1)\n    \n    # 量子ビット2に制御NOTゲートを適用\n    qc.cx(0, 2)\n    \n    # 量子ビット0を1/√3の位相に調整\n    qc.u1(-2 * 3.14159 / 3, 0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFADD5DA171D1", "submission_order": 2, "result": "WA", "execution_time": "1459 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    # 量子ビット0を|1⟩にするためにXゲートを適用\n    qc.x(0)\n    \n    # 量子ビット0にアダマールゲートを適用\n    qc.h(0)\n    \n    # 量子ビット1にHゲートを適用\n    qc.h(1)\n    \n    # 量子ビット2にHゲートを適用\n    qc.h(2)\n\n    # 各状態の位相を調整\n    pi = 3.14159\n    qc.rz(pi / 3, 0)  # |100⟩\n    qc.rz(pi / 3, 1)  # |010⟩\n    qc.rz(pi / 3, 2)  # |001⟩\n    \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFDE7D6BFE13A", "submission_order": 1, "result": "WA", "execution_time": "1535 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFDE7D6BFE13A", "submission_order": 2, "result": "RE", "execution_time": "1436 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n    qc.cx(0,1)\n    qc.cx(0,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFDE7D6BFE13A", "submission_order": 3, "result": "RE", "execution_time": "1396 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0)\n    qc.cx(0,1)\n    qc.cx(0,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFDE7D6BFE13A", "submission_order": 4, "result": "RE", "execution_time": "1403 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.ry(2 * math.atan(pow(2,0.5), 1))\n    qc.cx(1,0)\n    qc.cry(2*math.atan(1),1,2)\n    qc.cx(2,1)   \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFDE7D6BFE13A", "submission_order": 5, "result": "RE", "execution_time": "1513 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(pow(2,0.5), 0,1))\n    qc.cx(1,0)\n    qc.cry(2*math.atan(1),1,2)\n    qc.cx(2,1)   \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFDE7D6BFE13A", "submission_order": 6, "result": "RE", "execution_time": "1484 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(math.sqrt(2), 0,1))\n    qc.cx(1,0)\n    qc.cry(2*math.atan(1),1,2)\n    qc.cx(2,1)   \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFDE7D6BFE13A", "submission_order": 7, "result": "AC", "execution_time": "1581 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(2 * math.atan(math.sqrt(2)), 0,1)\n    qc.cx(1,0)\n    qc.cry(2*math.atan(1),1,2)\n    qc.cx(2,1)   \n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFF1911F70140", "submission_order": 1, "result": "WA", "execution_time": "1507 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(3)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.h(2)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFFAE60BB63F2", "submission_order": 1, "result": "RE", "execution_time": "1510 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.cx(0,1)\n    qc.ry(theta,1)\n    qc.cx(1,2)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFFAE60BB63F2", "submission_order": 2, "result": "RE", "execution_time": "1154 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    qc.ry(theta,1)\n    qc.ch(1,2)\n    qc.cx(2,1)\n    return qc\n'''"}
{"problem": "QPC003_A3", "user": "AFFAE60BB63F2", "submission_order": 3, "result": "RE", "execution_time": "1168 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta=4*math.atan(math.sqrt(6)/(3+math.sqrt(3)))\n    qc.ry(theta,0)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A003A4C8324EB", "submission_order": 1, "result": "AC", "execution_time": "1929 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    theta = math.asin(1.0 / math.sqrt(n))\n    qc.ry(2.0 * theta, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n\n    for i in range(1, n - 1):\n        theta = math.asin(1.0 / math.sqrt(n-i))\n        qc.cry(2.0*theta, i, i+1)\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A03D81149875C", "submission_order": 1, "result": "RE", "execution_time": "1209 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        theta=math.atan(2*math.atan(n-i))\n        qc.cry(theta,i-1,i)\n        qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A03D81149875C", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        theta=math.atan(2*math.atan(math.sqrt(n-i)))\n        qc.cry(theta,i-1,i)\n        qc.cx(i,i-)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A03D81149875C", "submission_order": 3, "result": "RE", "execution_time": "1338 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        theta=math.atan(2*math.atan(math.sqrt(n-i)))\n        qc.cry(theta,i-1,i)\n        qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A03D81149875C", "submission_order": 4, "result": "RE", "execution_time": "1638 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)]\n    qc.x(0)\n    for i in range(n-1):\n        qc.cry(theta[i],i,i+1)\n        qc.cx(i+1,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A03D81149875C", "submission_order": 5, "result": "AC", "execution_time": "1852 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)]\n    qc.x(0)\n    for i in range(n-1):\n        qc.cry(theta[i],i,i+1)\n        qc.cx(i+1,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A03DE0435906C", "submission_order": 1, "result": "WA", "execution_time": "2022 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.ry(acos(1-2/n), 0)\n    qc.x(0)\n    for i in range(1, n-1):\n        qc.cry(acos(1 - 2 / (n-i)), i-1, i)\n        qc.x(i)\n    for i in range(n-1):\n        qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A03DE0435906C", "submission_order": 2, "result": "WA", "execution_time": "1921 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.ry(acos(1-2/n), 0)\n    qc.x(0)\n    for i in range(1, n):\n        qc.cry(acos(1 - 2 / (n-i)), i-1, i)\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A0460F58C5610", "submission_order": 1, "result": "WA", "execution_time": "1456 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A0460F58C5610", "submission_order": 2, "result": "WA", "execution_time": "1671 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Define angles for controlled-Ry gates\n    theta = [2 * math.atan(math.sqrt(i)) for i in range(1, n)]  # Generate angles for controlled-Ry gates\n\n    # Start with the initial state by flipping the first qubit to |1⟩\n    qc.x(0)\n\n    # Apply controlled-Ry rotations and CNOT gates\n    for i in range(n - 1):\n        qc.cry(theta[i], i, i + 1)  # Apply controlled-Ry on qubits i and i+1\n        qc.cx(i + 1, i)             # Apply CNOT between qubits i+1 (control) and i (target)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A0460F58C5610", "submission_order": 3, "result": "AC", "execution_time": "2006 ms", "memory": "157 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)]\n \n    qc.x(0)\n \n    for i in range(n - 1):\n        qc.cry(theta[i], i, i + 1)\n        qc.cx(i + 1, i)\n \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A069404B4EC84", "submission_order": 1, "result": "RE", "execution_time": "2123 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        qc.cry(2*math.acos(1/math.sqrt(n-i)),i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A069404B4EC84", "submission_order": 2, "result": "AC", "execution_time": "2551 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        qc.cry(2*math.acos(1/math.sqrt(n-i)),i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A099B65030BFB", "submission_order": 1, "result": "AC", "execution_time": "1906 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = acos((2 - n)/n)\n    qc.u(theta, 0 , 0, 0)\n    for m in range(0, n - 2):\n      theta = acos((3 + m - n)/(n - m - 1))\n      qc.cu(theta, 0, 0, 0, m, m+1)\n    for m in range(n - 1):\n      qc.mcx(list(range(n - m - 1)), n - m - 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A09FA2083D8C4", "submission_order": 1, "result": "RE", "execution_time": "1588 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(2*acos(1/sqrt(n-i)),0);\n    for i in range(1,n-1):\n        qc.cry(2*acos(1/sqrt(n-i)),i-1,i)\n    for i in range(n-1,0,-1):\n        qc.cx(i-1,i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A09FA2083D8C4", "submission_order": 2, "result": "AC", "execution_time": "1838 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(n)),0)\n    for i in range(1,n-1):\n        qc.cry(2*math.acos(1/math.sqrt(n-i)),i-1,i)\n    for i in range(n-1,0,-1):\n        qc.cx(i-1,i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A109C204DF7C1", "submission_order": 1, "result": "AC", "execution_time": "1662 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, acos, sqrt\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if i:\n            qc.cry(acos(sqrt(1/(n-i))) * 2, i-1, i)\n        else:\n            qc.ry(acos(sqrt(1/(n-i))) * 2, i)\n    \n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 1, "result": "WA", "execution_time": "1349 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 2, "result": "WA", "execution_time": "1316 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 3, "result": "RE", "execution_time": "1436 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    amplitude = 1 /math.sqrt(n)\n\n    for i in range(n):\n        qc.ry(2 * amplitude, i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 4, "result": "WA", "execution_time": "1742 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    amplitude = 1 /math.sqrt(n)\n\n    for i in range(n):\n        qc.ry(2 * amplitude, i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 5, "result": "UGE", "execution_time": "1433 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    amplitude = 1 /math.sqrt(n)\n\n    state = [0] * (2**n)\n\n    for i in range(n):\n        state[2**i] = amplitude\n    qc.initialize(state)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 6, "result": "RE", "execution_time": "1191 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(HGate(), [0])\n\n    for i in range(1,n):\n        qc.append(CXGate(),[0,i])\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 7, "result": "RE", "execution_time": "1457 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.append(HGate(), [0])\n\n    for i in range(1,n):\n        qc.append(CXGate(), [0, i])\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n     qc.append(HGate(), [0])  # H on the first qubit\n\n    for i in range(1, n):\n        qc.append(CXGate(), [0, i])  \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 9, "result": "WA", "execution_time": "1343 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n):\n        qc.h(i) \n    qc.measure_all()\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 10, "result": "WA", "execution_time": "1368 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    qc.measure_all()\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A10CA3439EADE", "submission_order": 11, "result": "WA", "execution_time": "1272 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    qc.h(0)\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1AF2CAFE30A4", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    prob_amp = np.sqrt(1 / n)\n    rot_ang = 2 * np.arccos(prob_amp)\n\n    qc.x(0)\n\n    for i in range(n - 1):\n        comp_amp = np.sqrt(1 - i / n)\n        rot_ang = 2 * np.arccos(prob_amp / (comp_amp))\n        qc.cry(rot_ang, i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 1, "result": "RE", "execution_time": "1284 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * n\n    for i in range(n+1):\n        angle[i]=np.arccos(1/np.sqrt(i))\n    for i in range(n):\n        if i>n-2:\n            qc.cry(angle[n-i]*2,i,i+1)\n        else:\n            qc.cx(n-3,n-2)\n            qc.ch(n-2,n-1)\n            qc.cx(n-1,n-2)\n    for i in range(n):\n        if i<4:\n            pass\n        else:\n            for j in range(i):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 2, "result": "RE", "execution_time": "1178 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * n\n    for i in range(n+1):\n        angle[i]=np.arccos(1/np.sqrt(i))\n    for i in range(n):\n        if i>n-2:\n            qc.cry(angle[n-i]*2,i,i+1)\n        else:\n            qc.cx(n-3,n-2)\n            qc.ch(n-2,n-1)\n            qc.cx(n-1,n-2)\n    for i in range(n):\n        if i<4:\n            pass\n        else:\n            for j in range(i):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 3, "result": "RE", "execution_time": "1179 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * n\n    for i in range(n):\n        angle[i+1]=np.arccos(1/np.sqrt(i+1))\n    for i in range(n):\n        if i>n-2:\n            qc.cry(angle[n-i]*2,i,i+1)\n        else:\n            qc.cx(n-3,n-2)\n            qc.ch(n-2,n-1)\n            qc.cx(n-1,n-2)\n    for i in range(n):\n        if i<4:\n            pass\n        else:\n            for j in range(i):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 4, "result": "RE", "execution_time": "1402 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * n\n    for i in range(n):\n        angle[i+1]=np.arccos(1/np.sqrt(i+1))\n    for i in range(n):\n        if i>n-2:\n            qc.cry(angle[n-i]*2,i,i+1)\n        else:\n            qc.cx(n-3,n-2)\n            qc.ch(n-2,n-1)\n            qc.cx(n-1,n-2)\n    for i in range(n):\n        if i<4:\n            pass\n        else:\n            for j in range(i):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 5, "result": "RE", "execution_time": "1223 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * n\n\n    for i in range(n):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n):\n        if i<n-2:\n            qc.cry(angle[n-i]*2,i,i+1)\n        else:\n            qc.cx(n-3,n-2)\n            qc.ch(n-2,n-1)\n            qc.cx(n-1,n-2)\n    for i in range(n):\n        if i<4:\n            pass\n        else:\n            for j in range(i):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 6, "result": "RE", "execution_time": "1503 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * n\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n):\n        if i<n-2:\n            qc.cry(angle[n-i]*2,i,i+1)\n        else:\n            qc.cx(n-3,n-2)\n            qc.ch(n-2,n-1)\n            qc.cx(n-1,n-2)\n    for i in range(n):\n        if i<4:\n            pass\n        else:\n            for j in range(i):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 7, "result": "RE", "execution_time": "1703 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * n\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n):\n        if i<n-2:\n            qc.cry(angle[n-i]*2,i,i+1)\n        else:\n            qc.cx(n-2,n-3)\n            qc.ch(n-2,n-1)\n            qc.cx(n-1,n-2)\n    for i in range(n):\n        if i<4:\n            pass\n        else:\n            for j in range(i):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 8, "result": "RE", "execution_time": "1620 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * n\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n):\n        if i<n-2:\n            qc.cry(angle[n-i]*2,i,i+1)\n        else:\n            qc.cx(n-2,n-3)\n            qc.ch(n-2,n-1)\n            qc.cx(n-1,n-2)\n    for i in range(n+1):\n        if i<4:\n            pass\n        else:\n            for j in range(i):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 9, "result": "WA", "execution_time": "1841 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * (n+1)\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n-2):\n        qc.cry(angle[n-i]*2,i,i+1)\n\n    qc.cx(n-2,n-3)\n    qc.ch(n-2,n-1)\n    qc.cx(n-1,n-2)\n\n    for i in range(n+1):\n        if i<4:\n            pass\n        else:\n            for j in range(i-1):\n                qc.cx(n-1-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 10, "result": "RE", "execution_time": "1243 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * (n+1)\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n-2):\n        qc.cry(angle[n-i]*2,i,i+1)\n\n    qc.cx(n-2,n-3)\n    qc.ch(n-2,n-1)\n    qc.cx(n-1,n-2)\n\n    for i in range(n+1):\n        if i<4:\n            pass\n        else:\n            for j in range(i-1):\n                qc.cx(n-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 11, "result": "WA", "execution_time": "1793 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * (n+1)\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n-2):\n        qc.cry(angle[n-i]*2,i,i+1)\n\n    qc.cx(n-2,n-3)\n    qc.ch(n-2,n-1)\n    qc.cx(n-1,n-2)\n\n    for i in range(n+1):\n        if i<4:\n            pass\n        else:\n            for j in range(i-1):\n                qc.cx(n-1-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 12, "result": "WA", "execution_time": "1681 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * (n+1)\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n-2):\n        qc.cry(angle[n-i]*2,i,i+1)\n\n    qc.cx(n-2,n-3)\n    qc.ch(n-2,n-1)\n    qc.cx(n-1,n-2)\n\n    for i in range(n+1):\n        if i<4:\n            pass\n        else:\n            for j in range(i-1):\n                qc.cx(n-i+1+j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 13, "result": "WA", "execution_time": "1311 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * (n+1)\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n-2):\n        qc.cry(angle[n-i]*2,i,i+1)\n\n    qc.cx(n-2,n-3)\n    qc.ch(n-2,n-1)\n    qc.cx(n-1,n-2)\n\n    for i in range(n+1):\n        if i<4:\n            pass\n        else:\n            for j in range(i-1):\n                qc.cx(n-i+1+j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 14, "result": "WA", "execution_time": "2002 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    angle = [0] * (n+1)\n\n    for i in range(n+1):\n        if i==0:\n            pass\n        else:\n            angle[i]=np.arccos(1/np.sqrt(i))\n\n    for i in range(n-2):\n        qc.cry(angle[n-i]*2,i,i+1)\n\n    qc.cx(n-2,n-3)\n    qc.ch(n-2,n-1)\n    qc.cx(n-1,n-2)\n\n    for i in range(n+1):\n        if i<4:\n            pass\n        else:\n            for j in range(i-1):\n                qc.cx(n-1-j,n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1C5F56E70050", "submission_order": 15, "result": "AC", "execution_time": "1724 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==2:\n        qc.h(0)\n        qc.x(0)\n        qc.cx(0,1)\n        qc.x(0)\n        return qc\n    else:\n        qc.x(0)\n        angle = [0] * (n+1)\n\n        for i in range(n+1):\n            if i==0:\n                pass\n            else:\n                angle[i]=np.arccos(1/np.sqrt(i))\n\n        for i in range(n-2):\n            qc.cry(angle[n-i]*2,i,i+1)\n\n        qc.cx(n-2,n-3)\n        qc.ch(n-2,n-1)\n        qc.cx(n-1,n-2)\n\n        for i in range(n+1):\n            if i<4:\n                pass\n            else:\n                for j in range(i-1):\n                    qc.cx(n-1-j,n-i)\n        return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1CADEC397BB8", "submission_order": 1, "result": "WA", "execution_time": "1318 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range (1, n):\n        qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1CADEC397BB8", "submission_order": 2, "result": "WA", "execution_time": "1390 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n  \n    \n    for i in range(1, n):\n        qc.h(i)  \n    qc.x(0)  \n    \n    \n    for i in range(1, n):\n        qc.cx(i, 0)\n    \n    \n    for i in range(1, n):\n        qc.h(i)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1CADEC397BB8", "submission_order": 3, "result": "RE", "execution_time": "1132 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n  \n    \n    theta = 2 * atan(sqrt(n - 1))\n    qc.ry(theta, 0)\n    \n    for i in range(1, n):\n        theta = 2 * atan(sqrt(n - i - 1) / (i + 1))\n        qc.cry(theta, i - 1, i)\n    \n    for i in range(n - 2, -1, -1):\n        qc.cx(i, i + 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1CADEC397BB8", "submission_order": 4, "result": "WA", "execution_time": "1302 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, atan\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n  \n    \n    theta = 2 * atan(sqrt(n - 1))\n    qc.ry(theta, 0)\n    \n    for i in range(1, n):\n        theta = 2 * atan(sqrt(n - i - 1) / (i + 1))\n        qc.cry(theta, i - 1, i)\n    \n    for i in range(n - 2, -1, -1):\n        qc.cx(i, i + 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1CADEC397BB8", "submission_order": 5, "result": "WA", "execution_time": "1393 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, atan\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n  \n    \n    theta = 2 * atan(sqrt(n - 1))\n    qc.ry(theta, 0)\n    \n    for i in range(1, n):\n        theta = 2 * atan(sqrt(n - i - 1) / (i + 1))\n        qc.cry(theta, i - 1, i)\n    \n    for i in range(n - 2, -1, -1):\n        qc.cx(i, i + 1)\n    \n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A1CADEC397BB8", "submission_order": 6, "result": "AC", "execution_time": "1536 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, atan\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n  \n    \n    theta = 2 * atan(sqrt(n - 1))\n    qc.ry(theta, 0)\n    \n    for i in range(1, n-1):\n        theta = 2 * atan(sqrt(n - i - 1))\n        qc.cry(theta, i - 1, i)\n    \n    for i in range(0, n-1):\n        qc.cx(n-2-i, n-i -1)\n    \n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A21EA979689C7", "submission_order": 1, "result": "RE", "execution_time": "1579 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.ry(2 * math.acos(math.sqrt(2/3) ), 0)\n    for i in range(1, n):\n        qc.cry(2 * math.acos(math.sqrt((n-(i+1)) / (n-(i+1)+1)) ), 0,i)\n \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A21EA979689C7", "submission_order": 2, "result": "RE", "execution_time": "1214 ms", "memory": "153 MiB", "code": "'''python\ndef solve(n: int) -> QuantumCircuit:\n\n    qc = QuantumCircuit(n)\n    qc.ry(2 * math.acos(math.sqrt((n - 1) / n)), 0)\n\n    for i in range(1, n):\n        qc.cry(2 * math.acos(math.sqrt((n - i) / (n - i + 1))), 0, i)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A2448A6945483", "submission_order": 1, "result": "WA", "execution_time": "1299 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = math.acos(1 / math.sqrt(n - i))\n        qc.ry(2 * theta, i)\n        \n        # Apply controlled NOTs to ensure only one qubit is in the |1⟩ state per state\n        if i < n - 1:\n            qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 1, "result": "WA", "execution_time": "1575 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 2, "result": "WA", "execution_time": "1264 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 3, "result": "WA", "execution_time": "1366 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n\n    for i in range(1,n):\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 4, "result": "RE", "execution_time": "1308 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n            qc.u3(np.pi/2, 0, np.pi, i)  # 量子ビットを|+⟩状態にする\n            qc.u1(np.pi/2, i)  # 位相を調整して|1/sqrt(n)⟩状態にする\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 5, "result": "RE", "execution_time": "1531 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n            qc.u3(np.pi/2, 0, np.pi, i)  # 量子ビットを|+⟩状態にする\n            qc.u1(np.pi/2, i)  # 位相を調整して|1/sqrt(n)⟩状態にする\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, execute\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    # すべての量子ビットを|0⟩状態に初期化\n    for i in range(n):\n        qc.initialize([1, 0], i)\n    \n    # one-hot状態を生成\n    for i in range(n):\n        qc.u3(np.pi/2, 0, np.pi, i)  # 量子ビットを|+⟩状態にする\n        qc.u1(np.pi/2, i)  # 位相を調整して|1/sqrt(n)⟩状態にする\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 7, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, execute\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    # すべての量子ビットを|0⟩状態に初期化\n    for i in range(n):\n        qc.initialize([1, 0], i)\n    \n    # one-hot状態を生成\n    for i in range(n):\n        qc.u3(math.pi/2, 0, math.pi, i)  # 量子ビットを|+⟩状態にする\n        qc.u1(math.pi/2, i)  # 位相を調整して|1/sqrt(n)⟩状態にする\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 8, "result": "RE", "execution_time": "1598 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    # すべての量子ビットを|0⟩状態に初期化\n    for i in range(n):\n        qc.initialize([1, 0], i)\n    \n    # one-hot状態を生成\n    for i in range(n):\n        qc.u3(math.pi/2, 0, math.pi, i)  # 量子ビットを|+⟩状態にする\n        qc.u1(mat.pi/2, i)  # 位相を調整して|1/sqrt(n)⟩状態にする\n'''"}
{"problem": "QPC003_A4", "user": "A24E591CC238C", "submission_order": 9, "result": "RE", "execution_time": "1418 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    # すべての量子ビットを|0⟩状態に初期化\n    for i in range(n):\n        qc.initialize([1, 0], i)\n    \n    # one-hot状態を生成\n    for i in range(n):\n        qc.u3(math.pi/2, 0, math.pi, i)  # 量子ビットを|+⟩状態にする\n        qc.u1(math.pi/2, i)  # 位相を調整して|1/sqrt(n)⟩状態にする\n'''"}
{"problem": "QPC003_A4", "user": "A27960C87F4D0", "submission_order": 1, "result": "RE", "execution_time": "1417 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i) \n        \n    for i in range(n):\n        for j in range(i+1, n):\n            qc.cp(np.pi / n, i, j) \n\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A27960C87F4D0", "submission_order": 2, "result": "WA", "execution_time": "1252 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i) \n        \n    for i in range(n):\n        for j in range(i+1, n):\n            qc.cp(math.pi / n, i, j) \n\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A27960C87F4D0", "submission_order": 3, "result": "WA", "execution_time": "1309 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(2 * np.arccos(np.sqrt(1/n)), 0)\n    \n    for i in range(1, n):\n        theta = 2 * np.arccos(np.sqrt(1 / (n - i)))\n        qc.cx(i - 1, i)   \n        qc.ry(theta, i)                   \n        qc.cx(i - 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A27960C87F4D0", "submission_order": 4, "result": "WA", "execution_time": "1252 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    \n    for i in range(n-1):\n        theta = 2 * np.arccos(np.sqrt(1 / (n - i)))\n        qc.ry(theta, i+1)    \n        qc.cx(i, i-1)   \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A27960C87F4D0", "submission_order": 5, "result": "WA", "execution_time": "1238 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    \n    for i in range(n-1):\n        theta = 2 * np.arccos(np.sqrt(1 / (n - i)))\n        qc.ry(theta, i+1)    \n        qc.cx(i+1,i)   \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A27960C87F4D0", "submission_order": 6, "result": "WA", "execution_time": "1329 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    \n    for i in range(n-1):\n        theta = 2 * np.arccos(np.sqrt(1 / (n - i)))\n        qc.ry(theta, i+1)    \n        qc.cx(i,i+1)   \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A27960C87F4D0", "submission_order": 7, "result": "AC", "execution_time": "1964 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    \n    for i in range(n-1):\n        theta = 2 * np.arccos(np.sqrt(1 / (n - i)))\n        qc.cry(theta,i, i+1)    \n        qc.cx(i+1,i)   \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A28665AD3F65B", "submission_order": 1, "result": "RE", "execution_time": "1582 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    qc.x(0)\n    for i in range(n):\n        qc.x(i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A2C4B9AC3D5E0", "submission_order": 1, "result": "AC", "execution_time": "1736 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    a = (1 / n) ** 0.5\n    qc.ry(2 * math.acos(a), 0)\n    for i in range(n - 2):\n        a = (1 / (n - 1 - i)) ** 0.5\n        qc.cry(2 * math.acos(a), i, i + 1)\n    for i in range(1, n - 1)[::-1]:\n        for j in range(i):\n            qc.cx(i, j)\n    qc.x(n - 1)\n    for i in range(n - 1):\n        qc.cx(i, n - 1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A2D9DDFB5E073", "submission_order": 1, "result": "WA", "execution_time": "2666 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(1, n):\n        qc.ch(i-1, i)\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3294B7CFDAD0", "submission_order": 1, "result": "AC", "execution_time": "1820 ms", "memory": "158 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    acos,\n    # atan2,\n    sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.cry(asin(sqrt((n - i) / (n - i + 1))) * 2, i - 1, i)\n    for i in range(1, n):\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A337F39474332", "submission_order": 1, "result": "AC", "execution_time": "1769 ms", "memory": "157 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\ndef F_gate(circ,i,j,n,k) :\n  theta = np.arccos(np.sqrt(1/(n-k+1)))\n  circ.ry(-theta,j)       \n  circ.cz(i,j)\n  circ.ry(theta,j)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n - 1)\n    for i in range(n - 1):\n        F_gate(qc, n-i-1, n-i-2, n, i+1) \n\n    for i in range(n - 1):\n        qc.cx(n-i-2, n-i-1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A33BEFF6BDD13", "submission_order": 1, "result": "RE", "execution_time": "1185 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    theta = 2 * np.arccos(1 / 2)\n    \n    qc.ry(theta, 0)\n    qc.cry(theta, 0, 1)\n    qc.cry(theta, 0, 2)\n    qc.cry(theta, 0, 3)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A33BEFF6BDD13", "submission_order": 2, "result": "RE", "execution_time": "1702 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    theta = 2 * np.arccos(1 / 2)\n    \n    qc.ry(theta, 0)\n    qc.cry(theta, 0, 1)\n    qc.cry(theta, 0, 2)\n    qc.cry(theta, 0, 3)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3559DC92D056", "submission_order": 1, "result": "RE", "execution_time": "1905 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in reversed(range(1,n)):\n        qc.cry(2 * math.atan(math.sprt(n - i)), i - 1, i)\n        qc.cx(i - 1,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3559DC92D056", "submission_order": 2, "result": "RE", "execution_time": "1766 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in reversed(range(1,n)):\n        qc.cry(2 * math.atan(math.sprt(n - i)), i - 1, i)\n        qc.cx(i,i - 1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3559DC92D056", "submission_order": 3, "result": "RE", "execution_time": "1532 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n - 1):\n        qc.cry(2 * math.atan(math.sprt(n - i)), i, i + 1)\n        qc.cx(i + 1,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3559DC92D056", "submission_order": 4, "result": "AC", "execution_time": "2100 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)]\n    qc.x(0)\n    for i in range(n - 1):\n        qc.cry(theta[i], i, i + 1)\n        qc.cx(i + 1,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A35AA9E0E4E40", "submission_order": 1, "result": "AC", "execution_time": "2793 ms", "memory": "168 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.x(i)\n    theta = math.acos(math.sqrt((n-1)/(n))) * 2\n    qc.ry(theta, 0)\n    for i in range(1, n-1):\n        theta = math.acos(math.sqrt((n-i-1)/(n-i))) * 2\n        qc.append(RYGate(theta).control(i), [_ for _ in range(i + 1)])\n    qc.mcx([_ for _ in range(n - 1)], n - 1)\n    for i in range(n-1):\n        qc.x(i)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A39FDB3550EFF", "submission_order": 1, "result": "RE", "execution_time": "1896 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.mch(list(range(i)), i)\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A39FDB3550EFF", "submission_order": 2, "result": "RE", "execution_time": "1648 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i == 0:\n            qc.h(i)\n        else:\n            qc.mch(list(range(i)), i)\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A39FDB3550EFF", "submission_order": 3, "result": "RE", "execution_time": "1776 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i == 0:\n            qc.h(i)\n        else:\n            qc.append(HGate().control(i), list(range(i+1)))\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A39FDB3550EFF", "submission_order": 4, "result": "WA", "execution_time": "2017 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i == 0:\n            qc.h(i)\n        else:\n            qc.append(HGate().control(i), list(range(i+1)))\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3A716786D1A4", "submission_order": 1, "result": "RE", "execution_time": "1901 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(0, n):\n        qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1)\n        qc.cx(_ + 1, _)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3A716786D1A4", "submission_order": 2, "result": "RE", "execution_time": "1944 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(0, n):\n        qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1)\n        qc.cx(_ + 1, _)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3A716786D1A4", "submission_order": 3, "result": "AC", "execution_time": "2401 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(n - 1):\n        qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1)\n        qc.cx(_ + 1, _)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3CE59B2D10E4", "submission_order": 1, "result": "WA", "execution_time": "1555 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Paso 1: Aplicar Ry al primer qubit\n    theta = 2 * math.acos(1 / math.sqrt(n))\n    qc.ry(theta, 0)\n    \n    # Paso 2: Aplicar puertas controladas de Hadamard desde el primer qubit a los demás\n    for i in range(1, n):\n        qc.ch(0, i)\n    \n    # Paso 3: Aplicar una cadena de puertas CNOT entre los qubits 1 a n-1\n    for i in range(1, n-1):\n        qc.cx(i, i+1)\n    \n    # Paso 4: Aplicar puertas CNOT desde el primer qubit a los demás\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Paso 5: Aplicar una puerta X al primer qubit\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3CE59B2D10E4", "submission_order": 2, "result": "RE", "execution_time": "1228 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math as m\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    circuit.x(0)\n    \n    m = m.floor(n/2)\n\n    qubitT = 1\n    \n    \n    def _w_state_circuit(circuit, nn, mm, qubitC):    \n        \n        if nn == 0 and mm == 1:\n            pass #do nothing in this case\n        elif nn == 1 and mm == 2: #case (1,2)\n            circuit.cu3(m.pi/2, 0, 0, q[qubitC], q[qubitT])\n            circuit.cx(q[qubitT], q[qubitC])\n            qubitT = qubitT + 1\n        else: #otherwise\n            theta = 2*np.arccos(m.sqrt(nn/mm))\n            circuit.cu3(theta, 0, 0, q[qubitC], q[qubitT])\n            circuit.cx(q[qubitT], q[qubitC])\n            \n            qubitTRecurse = qubitT #saving target qubit index, used as control qubit for lower child\n            qubitT = qubitT + 1\n            \n            a = m.floor(nn/2)\n            b = m.floor(mm/2)\n            c = m.ceil(nn/2)\n            d = m.ceil(mm/2)\n            \n            if a == 1 and b == 1: #upper child (1,1) => (1,2) became upper child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitC)\n                #there is no lower child\n            elif c == 1 and d == 1: #lower child (1,1) => (1,2) became lower child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitTRecurse)\n                #there is no upper child\n            else:                       \n                #upper child\n                circuit = _w_state_circuit(circuit, a, b, qubitC)                 \n                #lower child\n                circuit = _w_state_circuit(circuit, c, d, qubitTRecurse)\n                    \n            return circuit\n    \n    qc = _w_state_circuit(qc, m, n, 0)\n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3CE59B2D10E4", "submission_order": 3, "result": "RE", "execution_time": "1157 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math as m\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    circuit.x(0)\n\n    qubitT = 1\n    \n    \n    def _w_state_circuit(circuit, nn, mm, qubitC):    \n        \n        if nn == 0 and mm == 1:\n            pass #do nothing in this case\n        elif nn == 1 and mm == 2: #case (1,2)\n            circuit.cu3(m.pi/2, 0, 0, q[qubitC], q[qubitT])\n            circuit.cx(q[qubitT], q[qubitC])\n            qubitT = qubitT + 1\n        else: #otherwise\n            theta = 2*np.arccos(m.sqrt(nn/mm))\n            circuit.cu3(theta, 0, 0, q[qubitC], q[qubitT])\n            circuit.cx(q[qubitT], q[qubitC])\n            \n            qubitTRecurse = qubitT #saving target qubit index, used as control qubit for lower child\n            qubitT = qubitT + 1\n            \n            a = m.floor(nn/2)\n            b = m.floor(mm/2)\n            c = m.ceil(nn/2)\n            d = m.ceil(mm/2)\n            \n            if a == 1 and b == 1: #upper child (1,1) => (1,2) became upper child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitC)\n                #there is no lower child\n            elif c == 1 and d == 1: #lower child (1,1) => (1,2) became lower child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitTRecurse)\n                #there is no upper child\n            else:                       \n                #upper child\n                circuit = _w_state_circuit(circuit, a, b, qubitC)                 \n                #lower child\n                circuit = _w_state_circuit(circuit, c, d, qubitTRecurse)\n                    \n            return circuit\n    \n    qc = _w_state_circuit(qc, m.floor(n/2), n, 0)\n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3CE59B2D10E4", "submission_order": 4, "result": "RE", "execution_time": "1241 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math as m\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    circuit.x(0)\n\n    qubitT = 1\n    \n    \n    def _w_state_circuit(circuit, nn, mm, qubitC):    \n        \n        if nn == 0 and mm == 1:\n            pass #do nothing in this case\n        elif nn == 1 and mm == 2: #case (1,2)\n            circuit.cu3(m.pi/2, 0, 0, qubitC, qubitT)\n            circuit.cx(qubitT, qubitC)\n            qubitT = qubitT + 1\n        else: #otherwise\n            theta = 2*np.arccos(m.sqrt(nn/mm))\n            circuit.cu3(theta, 0, 0, qubitC, qubitT)\n            circuit.cx(qubitT, qubitC)\n            \n            qubitTRecurse = qubitT #saving target qubit index, used as control qubit for lower child\n            qubitT = qubitT + 1\n            \n            a = m.floor(nn/2)\n            b = m.floor(mm/2)\n            c = m.ceil(nn/2)\n            d = m.ceil(mm/2)\n            \n            if a == 1 and b == 1: #upper child (1,1) => (1,2) became upper child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitC)\n                #there is no lower child\n            elif c == 1 and d == 1: #lower child (1,1) => (1,2) became lower child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitTRecurse)\n                #there is no upper child\n            else:                       \n                #upper child\n                circuit = _w_state_circuit(circuit, a, b, qubitC)                 \n                #lower child\n                circuit = _w_state_circuit(circuit, c, d, qubitTRecurse)\n                    \n            return circuit\n    \n    qc = _w_state_circuit(qc, m.floor(n/2), n, 0)\n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3CE59B2D10E4", "submission_order": 5, "result": "RE", "execution_time": "1476 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math as m\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n\n    qubitT = 1\n    \n    \n    def _w_state_circuit(circuit, nn, mm, qubitC):    \n        \n        if nn == 0 and mm == 1:\n            pass #do nothing in this case\n        elif nn == 1 and mm == 2: #case (1,2)\n            circuit.cu3(m.pi/2, 0, 0, qubitC, qubitT)\n            circuit.cx(qubitT, qubitC)\n            qubitT = qubitT + 1\n        else: #otherwise\n            theta = 2*np.arccos(m.sqrt(nn/mm))\n            circuit.cu3(theta, 0, 0, qubitC, qubitT)\n            circuit.cx(qubitT, qubitC)\n            \n            qubitTRecurse = qubitT #saving target qubit index, used as control qubit for lower child\n            qubitT = qubitT + 1\n            \n            a = m.floor(nn/2)\n            b = m.floor(mm/2)\n            c = m.ceil(nn/2)\n            d = m.ceil(mm/2)\n            \n            if a == 1 and b == 1: #upper child (1,1) => (1,2) became upper child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitC)\n                #there is no lower child\n            elif c == 1 and d == 1: #lower child (1,1) => (1,2) became lower child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitTRecurse)\n                #there is no upper child\n            else:                       \n                #upper child\n                circuit = _w_state_circuit(circuit, a, b, qubitC)                 \n                #lower child\n                circuit = _w_state_circuit(circuit, c, d, qubitTRecurse)\n                    \n            return circuit\n    \n    qc = _w_state_circuit(qc, m.floor(n/2), n, 0)\n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3CE59B2D10E4", "submission_order": 6, "result": "RE", "execution_time": "1303 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math as m\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n\n    qubitT = 1\n    \n    \n    def _w_state_circuit(circuit, nn, mm, qubitC):    \n        \n        if nn == 0 and mm == 1:\n            pass #do nothing in this case\n        elif nn == 1 and mm == 2: #case (1,2)\n            circuit.cu(m.pi/2, 0, 0, qubitC, qubitT)\n            circuit.cx(qubitT, qubitC)\n            qubitT = qubitT + 1\n        else: #otherwise\n            theta = 2*np.arccos(m.sqrt(nn/mm))\n            circuit.cu(theta, 0, 0, qubitC, qubitT)\n            circuit.cx(qubitT, qubitC)\n            \n            qubitTRecurse = qubitT #saving target qubit index, used as control qubit for lower child\n            qubitT = qubitT + 1\n            \n            a = m.floor(nn/2)\n            b = m.floor(mm/2)\n            c = m.ceil(nn/2)\n            d = m.ceil(mm/2)\n            \n            if a == 1 and b == 1: #upper child (1,1) => (1,2) became upper child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitC)\n                #there is no lower child\n            elif c == 1 and d == 1: #lower child (1,1) => (1,2) became lower child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitTRecurse)\n                #there is no upper child\n            else:                       \n                #upper child\n                circuit = _w_state_circuit(circuit, a, b, qubitC)                 \n                #lower child\n                circuit = _w_state_circuit(circuit, c, d, qubitTRecurse)\n                    \n            return circuit\n    \n    qc = _w_state_circuit(qc, m.floor(n/2), n, 0)\n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3CE59B2D10E4", "submission_order": 7, "result": "WA", "execution_time": "1692 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math as m\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    \n    \n    def _w_state_circuit(circuit, nn, mm, qubitC):    \n        global qubitT\n        \n        if nn == 0 and mm == 1:\n            pass #do nothing in this case\n        elif nn == 1 and mm == 2: #case (1,2)\n            circuit.cu(m.pi/2, 0, 0, 0, qubitC, qubitT)\n            circuit.cx(qubitT, qubitC)\n            qubitT = qubitT + 1\n        else: #otherwise\n            theta = 2*np.arccos(m.sqrt(nn/mm))\n            circuit.cu(theta, 0, 0, 0, qubitC, qubitT)\n            circuit.cx(qubitT, qubitC)\n            \n            qubitTRecurse = qubitT #saving target qubit index, used as control qubit for lower child\n            qubitT = qubitT + 1\n            \n            a = m.floor(nn/2)\n            b = m.floor(mm/2)\n            c = m.ceil(nn/2)\n            d = m.ceil(mm/2)\n            \n            if a == 1 and b == 1: #upper child (1,1) => (1,2) became upper child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitC)\n                #there is no lower child\n            elif c == 1 and d == 1: #lower child (1,1) => (1,2) became lower child\n                circuit = _w_state_circuit(circuit, 1, 2, qubitTRecurse)\n                #there is no upper child\n            else:                       \n                #upper child\n                circuit = _w_state_circuit(circuit, a, b, qubitC)                 \n                #lower child\n                circuit = _w_state_circuit(circuit, c, d, qubitTRecurse)\n                    \n        return circuit\n    \n    global qubitT\n    qubitT = 1\n    qc = _w_state_circuit(qc, m.floor(n/2), n, 0)\n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A3CE59B2D10E4", "submission_order": 8, "result": "WA", "execution_time": "1487 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Paso 1: Aplicar Ry al primer qubit\n    theta = 2 * math.acos(1 / math.sqrt(n))\n    qc.ry(theta, 0)\n    \n    # Paso 2: Aplicar puertas controladas de Hadamard desde el primer qubit a los demás\n    if n >= 3:\n        for i in range(1, n):\n            qc.ch(0, i)\n    \n        # Paso 3: Aplicar una cadena de puertas CNOT entre los qubits 1 a n-1\n        for i in range(1, n-1):\n            qc.cx(i, i+1)\n    \n    # Paso 4: Aplicar puertas CNOT desde el primer qubit a los demás\n    for i in range(1, n):\n        qc.cx(0, i)\n    \n    # Paso 5: Aplicar una puerta X al primer qubit\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4180631A2556", "submission_order": 1, "result": "AC", "execution_time": "1911 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, pi, sqrt\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n - 1):\n        theta = 2 * acos(1 / sqrt(n - i))\n        qc.cry(theta, i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A475A5F016619", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    desired_state = np.zeros(2**n)\n    for i in range(n):\n        desired_state[1 << i] = 1 / np.sqrt(n)\n        \n    qc.initialize(desired_state)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A475A5F016619", "submission_order": 2, "result": "WA", "execution_time": "1332 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CXGate\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.append(HGate(), [0])\n    \n    for i in range(1, n):\n        qc.append(CXGate(), [0, i])\n    \n    qc.global_phase = np.arccos(1 / np.sqrt(n))  \n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A49D7B03D88B3", "submission_order": 1, "result": "WA", "execution_time": "1913 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Create the superposition state\n    for i in range(n):\n        qc.x(i)          # Flip the i-th qubit to |1>\n        qc.h(i)          # Apply Hadamard to create superposition\n        qc.x(i)          # Flip back to |0>\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4C2D51B9C151", "submission_order": 1, "result": "AC", "execution_time": "2010 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.x(0)\n\n\tdef solve_for(l, r):\n\t\tif r - l == 1:\n\t\t\treturn\n\t\tm = l + r >> 1\n\t\ttheta = 2 * acos(sqrt(m - l) / sqrt(r - l))\n\t\tqc.cry(theta, l, m)\n\t\tqc.cx(m, l)\n\t\tsolve_for(l, m)\n\t\tsolve_for(m, r)\n\n\tsolve_for(0, n)\n\treturn qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 1, "result": "RE", "execution_time": "1279 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    x =  math.sqrt(1/3)\n    y =  math.sqrt(2/3)\n    \n    theta = 2 * math.atan(y/x)\n    qc.ry(theta, 1)\n    qc.ch(1,2)\n    qc.x(0)\n    qc.cx(1,0)\n    qc.cx(2,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 2, "result": "RE", "execution_time": "1637 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    x =  math.sqrt(1/3)\n    y =  math.sqrt(2/3)\n    \n    theta = 2 * math.atan(y/x)\n    qc.ry(theta, 1)\n    qc.ch(1,2)\n    qc.x(0)\n    qc.cx(1,0)\n    qc.cx(2,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 3, "result": "WA", "execution_time": "1428 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 1, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        qc.ry(theta, 1)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-1):\n        qc.cx(i+1,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 4, "result": "WA", "execution_time": "1437 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 1, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        qc.ry(theta, 1)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-1):\n        qc.cx(i+1,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 5, "result": "RE", "execution_time": "1259 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 1, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        qc.ry(theta, 1)\n\n    qc.x(0)\n    qc.cx(1,0)\n    qc.cx(2,1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 6, "result": "WA", "execution_time": "1431 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 1, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        qc.ry(theta, n-i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-1):\n        qc.cx(i+1,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 7, "result": "WA", "execution_time": "1568 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 1, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        qc.ry(theta, n - i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-1):\n        qc.cx(i+1,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 8, "result": "WA", "execution_time": "1545 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 1, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        if i == n:\n            qc.ry(theta, n - i)\n        else:\n            qc.cry(theta, n-i-1, n - i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-1):\n        qc.cx(i+1,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 9, "result": "WA", "execution_time": "1494 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 2, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        if i == n:\n            qc.ry(theta, n - i)\n        else:\n            qc.cry(theta, n-i-1, n - i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-1):\n        qc.cx(i+1,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 10, "result": "WA", "execution_time": "1510 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 1, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        if i == n:\n            qc.ry(theta, n - i)\n        else:\n            qc.cry(theta, n-i-1, n - i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-2):\n        qc.cx(i+1,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 1, -1):\n        x =  math.sqrt(1/i)\n        y =  math.sqrt(i-1/i)\n        theta = 2 * math.atan(y/x)\n        if i == n:\n            qc.ry(theta, n - i)\n        else:\n            qc.cry(theta, n-i-1, n - i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-):\n        qc.cx(i+1,i)\n\n\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 12, "result": "RE", "execution_time": "1778 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    x =  math.sqrt(1/3)\n    y =  math.sqrt(2/3)\n    theta = 2 * math.atan(y/x)\n    qc.ry(theta, 0)\n    x =  math.sqrt(1/2)\n    y =  math.sqrt(1/2)\n    theta = 2 * math.atan(y/x)\n    qc.cry(theta, 0, 1)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 13, "result": "RE", "execution_time": "1768 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    x =  math.sqrt(1/3)\n    y =  math.sqrt(2/3)\n    theta = 2 * math.atan(y/x)\n    qc.ry(theta, 0)\n    x =  math.sqrt(1/2)\n    y =  math.sqrt(1/2)\n    theta = 2 * math.atan(y/x)\n    qc.cry(theta, 0, 1)\n\n    qc.x(2)\n    qc.cx(0,2)\n    qc.cx(1,0,)\n\n    return qc\n\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        x =  math.sqrt(1/n-i)\n        y =  math.sqrt(n-i-1/n-i)\n        theta = 2 * math.atan(y/x)\n        if i == 0:\n            qc.ry(theta, i)\n        else:\n            qc.cry(theta, i-1, i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-2):\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 14, "result": "RE", "execution_time": "1210 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        x =  math.sqrt(1/n-i)\n        y =  math.sqrt(n-i-1/n-i)\n        theta = 2 * math.atan(y/x)\n        if i == 0:\n            qc.ry(theta, i)\n        else:\n            qc.cry(theta, i-1, i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-2):\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 15, "result": "RE", "execution_time": "1213 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        x =  math.sqrt(1/n-i)\n        y =  math.sqrt(n-i-1/n-i)\n        theta = 2 * math.atan(y/x)\n        if i == 0:\n            qc.ry(theta, i)\n        else:\n            qc.cry(theta, i-1, i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-2):\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A4E016A481935", "submission_order": 16, "result": "AC", "execution_time": "2272 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range( n - 1 ):\n        x =  math.sqrt(1/ (n-i))\n        y =  math.sqrt((n-i-1)/(n-i))\n        theta = 2 * math.atan(y/x)\n        if i == 0:\n            qc.ry(theta, i)\n        else:\n            qc.cry(theta, i-1, i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-2):\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta 2*math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n    for i in range(0,n-1):\n        theta = 2 * math.atan(math.sqrt(n-i))\n        qc.cry(theta,i,i+1)\n        qc.x(i)       \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n    for i in range(n-1):\n        theta = 2 * math.atan(math.sqrt(n-i-1))\n        qc.cry(theta,i,i+1)\n        qc.x(i)       \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n    for i in range(n-1):\n        theta = 2 * math.atan(math.sqrt(n-i-))\n        qc.cry(theta,[i],i+1)\n        qc.x(i)       \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 4, "result": "WA", "execution_time": "1445 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n\n    for i in range(n-1):\n        theta = 2 * math.atan(math.sqrt(n-i-1))\n        qc.cry(theta,i,i+1)\n        qc.x(i)       \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 5, "result": "WA", "execution_time": "1270 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n\n    for i in range(n-1):\n        theta = 2 * math.atan(math.sqrt(n-i-2))\n        qc.cry(theta,i,i+1)\n        qc.x(i)       \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 6, "result": "WA", "execution_time": "1260 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n    \n    for i in range(n-2):\n        theta = 2 * math.atan(math.sqrt(n-i-2))\n        qc.cry(theta,i,i+1)\n        qc.x(i)\n    qc.ch(n-2,n-1)\n    qc.x(n-2)    \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 7, "result": "WA", "execution_time": "1457 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n    \n    for i in range(n-2):\n        theta = 2 * math.atan(math.sqrt(n-i-2))\n        qc.cry(theta,i,i+1)\n    for i in range(n-1)[::-1]:\n        qc.cx(i+1,i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n    \n    for i in range(n-2):\n        theta = 2 * math.atan(math.sqrt(n-i-2))\n        qc.cry(theta,i,i+1)\n    \n    qc.(n-2,n-1)\n    for i in range(n-2)[::-1]:\n        qc.cx(i,i+1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A52624E1D9D63", "submission_order": 9, "result": "AC", "execution_time": "2027 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n    \n    for i in range(n-2):\n        theta = 2 * math.atan(math.sqrt(n-i-2))\n        qc.cry(theta,i,i+1)\n    \n    qc.cx(n-2,n-1)\n    for i in range(n-2)[::-1]:\n        qc.cx(i,i+1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A544FC4A45151", "submission_order": 1, "result": "WA", "execution_time": "1620 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # Rotación a cada qubit\n    theta = 2 * acos(1 / sqrt(n))  # Angulo\n    for qubit in range(n):\n        qc.ry(theta, qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A544FC4A45151", "submission_order": 2, "result": "WA", "execution_time": "1522 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, acos\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    \n    # Aplicamos la puerta CNOT\n    for qubit in range(1, n):\n        qc.cx(0, qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A56E693AA011D", "submission_order": 1, "result": "WA", "execution_time": "1328 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # Step 1: Apply Ry rotation on the first qubit\n    angle = 2 * np.arcsin(np.sqrt(1.0 / n))\n    qc.ry(angle, 0)\n    \n    # Step 2: Apply controlled Ry rotations on remaining qubits\n    for i in range(1, n):\n        angle = 2 * np.arcsin(np.sqrt(1.0 / (n - i)))\n        \n        # Apply a multi-controlled Ry gate\n        qc.mcry(angle, list(range(i)), i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A56E693AA011D", "submission_order": 2, "result": "WA", "execution_time": "1637 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # Step 1: Apply Ry rotation on the first qubit\n    angle = 2 * np.arcsin(np.sqrt(1.0 / n))\n    qc.ry(angle, 0)\n    \n    # Step 2: Apply controlled Ry rotations on remaining qubits\n    for i in range(1, n):\n        angle = 2 * np.arcsin(np.sqrt(1.0 / (n - i)))\n        \n        # Apply a multi-controlled phase gate\n        mc_phase_gate = MCPhaseGate(angle, num_ctrl_qubits=i)\n        qc.append(mc_phase_gate, list(range(i)) + [i])\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A56E693AA011D", "submission_order": 3, "result": "RE", "execution_time": "1176 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # Step 1: Apply Ry rotation on the first qubit\n    angle = 2 * np.arcsin(np.sqrt(1.0 / n))\n    qc.ry(angle, 0)\n    \n    # Step 2: Apply controlled Ry rotations on remaining qubits\n    for i in range(1, n):\n        angle = 2 * np.arcsin(np.sqrt(1.0 / (n - i)))\n        qc.mcz(angle, list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A56E693AA011D", "submission_order": 4, "result": "WA", "execution_time": "1555 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # Step 1: Apply Ry rotation on the first qubit\n    angle = 2 * np.arcsin(np.sqrt(1.0 / n))\n    qc.ry(angle, 0)\n    \n    # Step 2: Apply controlled Ry rotations on remaining qubits\n    for i in range(1, n):\n        angle = 2 * np.arcsin(np.sqrt(1.0 / (n - i)))\n        qc.mcrz(angle, list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A596EFACEE8C1", "submission_order": 1, "result": "AC", "execution_time": "2929 ms", "memory": "170 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for k in range(n):\n        theta = 2 * math.asin(1 / math.sqrt(n - k))\n        if k == 0:\n            qc.ry(theta, 0)\n        else:\n            # Apply X to qubits 0..k-1\n            for i in range(k):\n                qc.x(i)\n            # Create a controlled Ry gate with k controls (all must be 1)\n            cry_gate = RYGate(theta).control(k, ctrl_state='1'*k)\n            qc.append(cry_gate, list(range(k)) + [k])\n            # Apply X again to qubits 0..k-1\n            for i in range(k):\n                qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A5D1E311D0483", "submission_order": 1, "result": "RE", "execution_time": "1385 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve() -> QuantumCircuit:\n    # qc = QuantumCircuit(3)z\n    # # Write your code here:\n    # q = QuantumRegister(3) \n\n    def F_gate(circ,q,i,j,n,k) :\n        theta = np.arccos(np.sqrt(1/(n-k+1)))\n        circ.ry(-theta,q[j])       \n        circ.cz(q[i],q[j])\n        circ.ry(theta,q[j])\n        circ.barrier(q[i])\n    # Define the cxrv gate which uses reverse CNOT instead of CNOT\n    def  cxrv(circ,q,i,j) :\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.cx(q[j],q[i])\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.barrier(q[i],q[j])\n\n    \n    # 3-qubit W state\n    flag_qx2 = True\n\n    n = 4\n    q_w = QuantumRegister(n) \n\n    qc = QuantumCircuit(q_w) \n\n    qc.x(q_w[2]) #start is |100>\n    F_gate(qc,q_w,2,1,3,1) # Applying F12\n    F_gate(qc,q_w,1,0,3,2) # Applying F23\n\n    if flag_qx2 : # option ibmqx2 \n        qc.cx(q_w[1],q_w[2]) # cNOT 21\n        qc.cx(q_w[0],q_w[1]) # cNOT 32\n        \n    else :        # option ibmqx4  \n        cxrv(qc,q_w,1,2)\n        cxrv(qc,q_w,0,1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A5D1E311D0483", "submission_order": 2, "result": "RE", "execution_time": "1269 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    # qc = QuantumCircuit(n)\n    # Write your code here:\n    q_w = QuantumRegister(n) \n\n    qc = QuantumCircuit(q_w) \n\n\n    def F_gate(circ,q,i,j,n,k) :\n        theta = np.arccos(np.sqrt(1/(n-k+1)))\n        circ.ry(-theta,q[j])       \n        circ.cz(q[i],q[j])\n        circ.ry(theta,q[j])\n        circ.barrier(q[i])\n    # Define the cxrv gate which uses reverse CNOT instead of CNOT\n    def  cxrv(circ,q,i,j) :\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.cx(q[j],q[i])\n        circ.h(q[i])\n        circ.h(q[j])\n        circ.barrier(q[i],q[j])\n\n    # 4-qubit W state\n    # n = 4\n    # q = QuantumRegister(n) \n    # c = ClassicalRegister(n)\n    # W_states = QuantumCircuit(q,c) \n\n    qc.x(q[3]) #start is |1000>\n    F_gate(qc,q,3,2,4,1) # Applying F12\n    F_gate(qc,q,2,1,4,2) # Applying F23\n    F_gate(qc,q,1,0,4,3) # Applying F34        \n    cxrv(qc,q,2,3) # cNOT 21\n    qc.cx(q[1],q[2]) # cNOT 32\n    qc.cx(q[0],q[1]) # cNOT 43\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A65A1EF0FBF36", "submission_order": 1, "result": "AC", "execution_time": "2449 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)    \n\n    for i in range(0, n-1):\n        theta = math.atan(math.sqrt(n-i-1)) * 2\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A6B0EDA1EEE42", "submission_order": 1, "result": "WA", "execution_time": "1325 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A6E9820C74560", "submission_order": 1, "result": "AC", "execution_time": "2182 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, atan\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    theta = 2*atan(sqrt(n-1))\n    qc.ry(theta, 0)\n    for i in range(1, n-1):\n        theta = 2*atan(sqrt(n-1-i))\n        qc.cry(theta, i-1, i)\n    for i in range(0, n-1):\n        qc.cx(n-i-2, n-i-1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A735662C11D5C", "submission_order": 1, "result": "AC", "execution_time": "2663 ms", "memory": "169 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(math.asin(1/math.sqrt(n))*2, 0)\n    for i in range(1, n):\n        for j in range(i):\n            qc.x(j)\n        qc.append(RYGate(math.asin(1/math.sqrt(n-i))*2).control(i), range(i+1))\n        for j in range(i):\n            qc.x(j)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A4", "user": "A7457B805C611", "submission_order": 1, "result": "AC", "execution_time": "1881 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    theta_list=[0,0]\n    for i in range(2,n+1):\n        theta_list.append(4*math.atan(math.sqrt(i*(i-1))/(i+math.sqrt(i))))\n            \n    qc.ry(theta_list[n],0)\n    for i in range(n-2):\n        qc.cry(theta_list[n-i-1],i,i+1)\n    for i in range(n-1)[::-1]:\n        qc.cx(i,i+1)    \n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A74C263C99CA7", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    qc.cx(n - 1)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n - 1)\n        qc.cx(i, i - 1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A74C263C99CA7", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    qc.x(n - 1)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n - 1)\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A74C263C99CA7", "submission_order": 3, "result": "WA", "execution_time": "1689 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    qc.x(n - 1)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n - 1):\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A74C263C99CA7", "submission_order": 4, "result": "WA", "execution_time": "1715 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n\n    for i in range(n - 1):\n        qc.ch(i, i + 1)\n\n    qc.x(n - 1)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n - 1):\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A74C263C99CA7", "submission_order": 5, "result": "RE", "execution_time": "1889 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(n - 1))\n    qc.ry(th, 0)\n\n    for i in range(n - 1):\n        th = 2 * math.atan(math.sqrt(n - 2 - i))\n        qc.cry(th, i, i + 1)\n\n    qc.x(n - 1)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n - 1):\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A74C263C99CA7", "submission_order": 6, "result": "AC", "execution_time": "2427 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    th = 2 * math.atan(math.sqrt(n - 1))\n    qc.ry(th, 0)\n\n    for i in range(n - 1):\n        th = 2 * math.atan(math.sqrt(n - 2 - i))\n        qc.cry(th, i, i + 1)\n\n    qc.x(n - 1)\n    qc.cx(0, n - 1)\n\n    for i in range(1, n - 1):\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A78BBB3CA5E9D", "submission_order": 1, "result": "RE", "execution_time": "1355 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        p = math.sqrt(1/(n-i))\n        qc.ry(2*math.acos(p), i)\n        qc.cx(i, i+1)\n        qc.x(i)\n\n    qc.ch(n-1, n)\n    qc.cx(n, n-1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A78BBB3CA5E9D", "submission_order": 2, "result": "RE", "execution_time": "1432 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        p = math.sqrt(1/(n-i))\n        qc.ry(2*math.acos(p), i)\n        qc.cx(i, i+1)\n        qc.x(i)\n\n    qc.ch(n-2, n-1)\n    qc.cx(n-1, n-2)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A78BBB3CA5E9D", "submission_order": 3, "result": "RE", "execution_time": "1656 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        p = math.sqrt(1/(n-i))\n        qc.ry(2*math.acos(p), i)\n        qc.cx(i, i+1)\n        qc.x(i)\n\n    # qc.ch(n-2, n-1)\n    # qc.cx(n-, n-2)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A78BBB3CA5E9D", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        p = math.sqrt(1/(n-i))\n        qc.ry(2*math.acos(p), i)\n        qc.cx(i, i+1)\n        qc.x(i)\n\n    qc.ch(n-2, n-1)\n    qc.cx(n-, n-2)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A78BBB3CA5E9D", "submission_order": 5, "result": "WA", "execution_time": "2461 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        p = math.sqrt(1/(n-i))\n        qc.ry(2*math.acos(p), i)\n        qc.cx(i, i+1)\n        qc.x(i)\n\n    qc.ch(n-2, n-1)\n    qc.cx(n-1, n-2)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A7D25DE87BBDE", "submission_order": 1, "result": "WA", "execution_time": "1319 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    theta = 2 * math.acos(1 / math.sqrt(n))\n    \n    qc.x(n - 1)\n    qc.ry(theta, 0)\n    \n    for i in range(1, n - 1):\n        qc.ch(i - 1, i)\n    \n    qc.cx(0, n - 1)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A7D25DE87BBDE", "submission_order": 2, "result": "RE", "execution_time": "1212 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=3\n    qc = QuantumCircuit(n)\n    \n    'theta = 2 * math.acos(1 / math.sqrt(n))'\n    \n    qc.x(n - 1)\n    qc.ry(theta, 0)\n    \n    for i in range(1, n - 1):\n        qc.ch(i - 1, i)\n    \n    qc.cx(0, n - 1)\n\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A7D25DE87BBDE", "submission_order": 3, "result": "WA", "execution_time": "1482 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n  \n    qc = QuantumCircuit(n)\n\n\n    theta = 2 * math.acos(1 / math.sqrt(n))\n    \n\n    qc.x(n - 1)\n\n    qc.ry(theta, 0)\n    \n\n    for i in range(1, n - 1):\n        qc.ch(i - 1, i)\n    \n\n    for i in range(1,n):\n        qc.cx(n - i - 1, n - i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A883D36C18B04", "submission_order": 1, "result": "AC", "execution_time": "1781 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    split(qc, 0, n)\n\n    return qc\n\ndef split(qc, stIncl, edExcl):\n    if stIncl + 1 == edExcl:\n        return\n\n    mid = (stIncl + edExcl) // 2\n    left = mid - stIncl\n    right = edExcl - mid\n    print(f'{left=} {right=}')\n\n    angle = 2*math.atan(math.sqrt(right/left))\n    qc.cry(angle, stIncl, mid)\n    qc.cx(mid, stIncl)\n\n    split(qc, stIncl, mid)\n    split(qc, mid, edExcl)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A8B444D8B9172", "submission_order": 1, "result": "AC", "execution_time": "1930 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)]\n \n    qc.x(0)\n \n    for i in range(n - 1):\n        qc.cry(theta[i], i, i + 1)\n        qc.cx(i + 1, i)\n \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A8CF0180140B4", "submission_order": 1, "result": "AC", "execution_time": "1884 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import asin\n\n\ndef move(qc, f, t, ratio):\n    theta = 2 * asin(ratio**0.5)\n    qc.cry(theta, f, t)\n    qc.cx(t, f)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    parent = [None]\n    for i in range(1, n):\n        for r in (8, 4, 2, 1):\n            if i & r:\n                parent.append(i - r)\n                break\n\n    # print(parent)\n\n    ww = [0] * n\n    for i in range(n - 1, -1, -1):\n        ww[i] += 1 / n\n        if parent[i] is not None:\n            ww[parent[i]] += ww[i]\n\n    # print(ww)\n\n    xx = [0] * n\n    xx[0] = 1\n\n    for i in range(1, n):\n        p = parent[i]\n        move(qc, p, i, ww[i] / xx[p])\n        xx[p] -= ww[i]\n        xx[i] = ww[i]\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A8EA69EACC806", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n\n    count = 1\n\n    # queue = [(a, b, control bit of CRy), ...]\n    queue = [(n // 2, n, 0)]\n\n    # breadth first search\n    while len(queue):\n        a, b, control = queue.pop(0)\n\n        if a == 0:\n            continue\n\n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n\n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n\n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n\n        count += 1\n\n    return qc\n\n\nif __name__ == \"__main__\":\n    from qiskit.quantum_info import Statevector\n    import numpy as np\n\n    n = 3\n    qc = solve(n)\n    sv = Statevector(qc)\n    print(sv)\n    print(qc)\n    print(f\"{qc.depth() = }\")\n    # sv = Statevector.from_label('01000')\n    # print(sv.evolve(qc))\n'''"}
{"problem": "QPC003_A4", "user": "A8ECB599D8C10", "submission_order": 1, "result": "AC", "execution_time": "1867 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(1, n):\n        qc.cry(2 * math.acos(1.0 / math.sqrt(n - i + 1)), i - 1, i)\n    \n    for i in range(1, n):\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A90B6F2C8381A", "submission_order": 1, "result": "RE", "execution_time": "1402 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, atan\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        t = 2*asin(sqrt(1/(n-i)))\n        qc.cry(t, 0, i+1)\n        qc.cx(i+1, 0)\n        \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A90B6F2C8381A", "submission_order": 2, "result": "AC", "execution_time": "1724 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt, asin\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        t = 2*asin(sqrt(1/(n-i)))\n        qc.cry(t, 0, i+1)\n        qc.cx(i+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A966EED31F255", "submission_order": 1, "result": "AC", "execution_time": "2938 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        print(i)\n        theta = 2 * math.atan(math.sqrt(n - i - 1))\n        print(math.cos(theta/2))\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9A67E2BB6C22", "submission_order": 1, "result": "AC", "execution_time": "1730 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nimport numpy\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(n - 1):\n        theta = 2 * numpy.arccos(math.sqrt(1/(n - i)))\n        qc.cry(theta, i, i + 1)\n    \n    for i in range(n - 1):\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9AEE2D7F7B64", "submission_order": 1, "result": "RE", "execution_time": "1465 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    theta = 2 * np.arcsin(np.sqrt(1/3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.cx(0, 2)\n\n\n    theta = 2 * np.arcsin(np.sqrt(1/n))\n    qc.ry(theta, 0)\n\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9AEE2D7F7B64", "submission_order": 2, "result": "WA", "execution_time": "1395 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # 回転角 θ を計算 (θ = 2 * arcsin(√(1/n)))\n    theta = 2 * math.asin(math.sqrt(1/n))\n\n    # 第1量子ビットに Ry ゲートを適用して重ね合わせを作成\n    qc.ry(theta, 0)\n\n    # 第1量子ビットが 1 のとき、他の量子ビットにエンタングルメントを作成\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9B4815FB0282", "submission_order": 1, "result": "WA", "execution_time": "1422 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(n-1):\n        theta = 2 * math.acos((n-i)**-0.5)\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9B4815FB0282", "submission_order": 2, "result": "AC", "execution_time": "1727 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(n-1):\n        theta = 2 * math.acos((n-i)**-0.5)\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, i)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9C50D9C11712", "submission_order": 1, "result": "RE", "execution_time": "1491 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        theta = math.atan(1/math.sqrt(n-i))*2\n        qc.cry(theta, 0, i)\n        qc.cx(i,0)\n    qc.x(0)\n    for i in range(1,n):\n        qc.cx(i,0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9C50D9C11712", "submission_order": 2, "result": "RE", "execution_time": "1175 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        theta = math.atan(math.sqrt(n-i))*2\n        qc.cry(theta, i - 1, i)\n        qc.cx(i,i - 1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9C50D9C11712", "submission_order": 3, "result": "AC", "execution_time": "1646 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        theta = math.atan(math.sqrt(n-i))*2\n        qc.cry(theta, i-1, i)\n        qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "A9CB640D3C799", "submission_order": 1, "result": "RE", "execution_time": "1377 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AA7CCD31CA864", "submission_order": 1, "result": "RE", "execution_time": "1238 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ry(2 * math.acos(1 / math.sqrt(n)), 0)\n    \n    for i in range(1, n):\n        angle = 2 * math.acos(math.sqrt((n - i) / (n - i + 1)))\n        qc.cry(angle, i - 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AA7CCD31CA864", "submission_order": 2, "result": "WA", "execution_time": "1302 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ry(2 * math.acos(1 / math.sqrt(n)), 0)\n    \n    for i in range(1, n):\n        angle = 2 * math.acos(math.sqrt((n - i) / (n - i + 1)))\n        qc.cry(angle, i - 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AA7CCD31CA864", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport mat\n\ndef F_gate(circ,q,i,j,n,k) :\n    theta = math.acos(math.sqrt(1/(n-k+1)))\n    circ.ry(-theta,q[j])       \n    circ.cz(q[i],q[j])\n    circ.ry(theta,q[j])\n    circ.barrier(q[i])\n\ndef  cxrv(circ,q,i,j) :\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.cx(q[j],q[i])\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.barrier(q[i],q[j])\n\ndef solve(n: int) -> QuantumCircuit:\n    q = QuantumRegister(n)\n    qc = QuantumCircuit(q)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(1, n):\n        F_gate(qc, q, n-i, n-i-1, n, i)\n    for i in range(1, n):\n        cxrv(qc, q, n-i-1, n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AA7CCD31CA864", "submission_order": 4, "result": "AC", "execution_time": "1747 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef F_gate(circ,q,i,j,n,k) :\n    theta = math.acos(math.sqrt(1/(n-k+1)))\n    circ.ry(-theta,q[j])       \n    circ.cz(q[i],q[j])\n    circ.ry(theta,q[j])\n    circ.barrier(q[i])\n\ndef  cxrv(circ,q,i,j) :\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.cx(q[j],q[i])\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.barrier(q[i],q[j])\n\ndef solve(n: int) -> QuantumCircuit:\n    q = QuantumRegister(n)\n    qc = QuantumCircuit(q)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(1, n):\n        F_gate(qc, q, n-i, n-i-1, n, i)\n    for i in range(1, n):\n        cxrv(qc, q, n-i-1, n-i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AAC7A3E020E2B", "submission_order": 1, "result": "WA", "execution_time": "2186 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.ry(math.asin(1/math.sqrt(n-i)), i)\n        qc.x(i)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AAC7A3E020E2B", "submission_order": 2, "result": "WA", "execution_time": "1835 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.ry(2*math.asin(1/math.sqrt(n-i)), i)\n        qc.x(i)\n        qc.cx(i,i+1)\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AAC7A3E020E2B", "submission_order": 3, "result": "WA", "execution_time": "1781 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(2*math.asin(1/math.sqrt(n)), 0)\n    for i in range(n-1):\n        qc.x(i)\n        qc.cry(2*math.asin(1/math.sqrt(n-i-1)),i,i+1)\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AACD11E48F8A5", "submission_order": 1, "result": "WA", "execution_time": "1520 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    import numpy as np\n    qc.ry(2 * np.arccos(1 / np.sqrt(n)), 0)\n    for i in range(n-1):\n        qc.ch(0, i+1)\n        qc.cx(n-i-1, n-i-2)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AACD11E48F8A5", "submission_order": 2, "result": "WA", "execution_time": "1379 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    import numpy as np\n    def theta(k):\n        return np.arccos(np.sqrt(1 / (n-k+1)))\n\n    for k in range(n-1):\n        qc.ry(- theta(k), k+1)\n        qc.cz(k, k+1)\n        qc.ry(theta(k), k+1)\n\n    for i in range(n-1):\n        qc.cx(i+0, i+1)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AAF05F377A3C1", "submission_order": 1, "result": "AC", "execution_time": "1887 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.r(2*math.acos(1.0/math.sqrt(n)), math.pi/2, 0)\n    for i in range(n-2):\n      qc.crx(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      qc.cp(math.pi/2, i, i+1)\n    for i in range(n-1):\n      qc.cx(n-2-i, n-1-i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AB818321B8959", "submission_order": 1, "result": "AC", "execution_time": "1872 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    for i in range(n-1):\n        theta = 2 * math.acos(1 / math.sqrt(n - i))\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, i)\n \n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB1E7B0FE23D", "submission_order": 1, "result": "RE", "execution_time": "1216 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        #前側をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            qc.mcry(theta, list(range(i)), i+1)\n        else:\n            qc.ry(theta, 0)\n        for j in range(i+1):\n            qc.x(j)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB1E7B0FE23D", "submission_order": 2, "result": "WA", "execution_time": "1689 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        #前側をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            qc.mcry(theta, list(range(i)), i)\n        else:\n            qc.ry(theta, 0)\n        for j in range(i+1):\n            qc.x(j)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB1E7B0FE23D", "submission_order": 3, "result": "WA", "execution_time": "1256 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        #前側をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n        else:\n            qc.ry(theta, 0)\n        for j in range(i+1):\n            qc.x(j)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB1E7B0FE23D", "submission_order": 4, "result": "WA", "execution_time": "1332 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        #前側をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n        else:\n            qc.ry(theta, 0)\n    for j in range(i+1):\n        qc.x(j)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB1E7B0FE23D", "submission_order": 5, "result": "WA", "execution_time": "1527 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        #前側0をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n        else:\n            qc.ry(theta, 0)\n        for j in range(i):\n            qc.x(j)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB1E7B0FE23D", "submission_order": 6, "result": "WA", "execution_time": "1578 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        #前側0をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n        else:\n            qc.ry(theta, 0)\n        #0->1にしてたやつを戻す\n        for j in range(i):\n            qc.x(j)\n    for i in range(n-1):\n        qc.x(i)\n    qc.mcx(list(range(n-1)), n-1)\n    for i in range(n-1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB1E7B0FE23D", "submission_order": 7, "result": "WA", "execution_time": "1380 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        #前側0をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n        else:\n            qc.ry(theta, 0)\n        qc.x(i)\n        #0->1にしてたやつを戻す\n        for j in range(i):\n            qc.x(j)\n    for i in range(n-1):\n        qc.x(i)\n    qc.mcx(list(range(n-1)), n-1)\n    for i in range(n-1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB1E7B0FE23D", "submission_order": 8, "result": "AC", "execution_time": "2262 ms", "memory": "167 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        #前側0をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n            qc.mcx(list(range(i)), i)\n        else:\n            qc.ry(theta, 0)\n            qc.x(0)\n\n        #0->1にしてたやつを戻す\n        for j in range(i):\n            qc.x(j)\n    for i in range(n-1):\n        qc.x(i)\n    qc.mcx(list(range(n-1)), n-1)\n    for i in range(n-1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "ABB2792CA11FE", "submission_order": 1, "result": "WA", "execution_time": "1437 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(k: int) -> float:\n    return math.asin(math.sqrt((k-1)/k)) * 2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(theta(n), 0)\n    for i in range(1, n):\n        qc.x(i-1)\n        qc.cry(theta(n-i), i-1, i)\n        qc.x(i-1)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_A4", "user": "ABB2792CA11FE", "submission_order": 2, "result": "WA", "execution_time": "1662 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(k: int) -> float:\n    return math.acos(math.sqrt((k-1)/k)) * 2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(theta(n), 0)\n    for i in range(1, n):\n        qc.cry(theta(n-i), i-1, i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_A4", "user": "ABB2792CA11FE", "submission_order": 3, "result": "WA", "execution_time": "1437 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(k: int) -> float:\n    return math.asin(math.sqrt((k-1)/k)) * 2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.cry(theta(n), i-1, i)\n        qc.cx(i, i-1)\n        qc.x(i)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_A4", "user": "ABB2792CA11FE", "submission_order": 4, "result": "WA", "execution_time": "1366 ms", "memory": "156 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(k: int) -> float:\n    return math.asin(math.sqrt((k-1)/k)) * 2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.cry(theta(n-i+1), i-1, i)\n        qc.cx(i, i-1)\n        qc.x(i)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_A4", "user": "ABB2792CA11FE", "submission_order": 5, "result": "WA", "execution_time": "1223 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(k: int) -> float:\n    return math.acos(math.sqrt((k-1)/k)) * 2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.cry(theta(n-i+1), i-1, i)\n        qc.cx(i, i-1)\n        qc.x(i)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_A4", "user": "ABB2792CA11FE", "submission_order": 6, "result": "WA", "execution_time": "1588 ms", "memory": "156 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(k: int) -> float:\n    return math.acos(math.sqrt((k-1)/k)) * 2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.cry(theta(n-i+1), i-1, i)\n        qc.cx(i, i-1)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_A4", "user": "ABB2792CA11FE", "submission_order": 7, "result": "AC", "execution_time": "1918 ms", "memory": "156 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(k: int) -> float:\n    return math.asin(math.sqrt((k-1)/k)) * 2\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.cry(theta(n-i+1), i-1, i)\n        qc.cx(i, i-1)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_A4", "user": "AC35CE67CC347", "submission_order": 1, "result": "AC", "execution_time": "2043 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    prob_amp = np.sqrt(1 / n)\n    rot_ang = 2 * np.arccos(prob_amp)\n\n    qc.x(0)\n\n    for i in range(n - 1):\n        comp_amp = np.sqrt(1 - i / n)\n        rot_ang = 2 * np.arccos(prob_amp / (comp_amp))\n        qc.cry(rot_ang, i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AC63504B6FEA8", "submission_order": 1, "result": "RE", "execution_time": "1503 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc_w = QuantumCircuit(n)\n    # Write your code here:\n    \n    prob_amp = np.sqrt(1/n)\n    rot_ang = 2*np.arccos(prob_amp)\n    \n    qc_w = QuantumCircuit(n) \n    \n    # probability redistribution\n    qc_w.ry(rot_ang,0)\n    \n    for i in range(1,n-1):\n        comp_amp = np.sqrt(1-i/n)\n        rot_ang = 2*np.arccos(prob_amp/(comp_amp))\n        qc_w.cry(rot_ang,i-1,i)\n    \n    # state reshuffling\n    for i in range(n-1, 0, -1):\n        qc_w.cx(i-1,i)\n    \n    qc_w.x(0)\n    \n    return qc_w\n'''"}
{"problem": "QPC003_A4", "user": "AC63504B6FEA8", "submission_order": 2, "result": "AC", "execution_time": "1932 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc_w = QuantumCircuit(n)\n    # Write your code here:\n    \n    prob_amp = np.sqrt(1/n)\n    rot_ang = 2*np.arccos(prob_amp)\n    \n    qc_w = QuantumCircuit(n) \n    \n    # probability redistribution\n    qc_w.ry(rot_ang,0)\n    \n    for i in range(1,n-1):\n        comp_amp = np.sqrt(1-i/n)\n        rot_ang = 2*np.arccos(prob_amp/(comp_amp))\n        qc_w.cry(rot_ang,i-1,i)\n    \n    # state reshuffling\n    for i in range(n-1, 0, -1):\n        qc_w.cx(i-1,i)\n    \n    qc_w.x(0)\n    \n    return qc_w\n'''"}
{"problem": "QPC003_A4", "user": "AD2171ACABF0A", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    theta = [2 * math.atan(math.sqrt(i)) range(n - 1,0,-1)]\n    for i in range(n - 1):\n        qc.cry(theta[i],i,i + 1)\n        qc.cx(i + 1,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AD2171ACABF0A", "submission_order": 2, "result": "AC", "execution_time": "2056 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1,0,-1)]\n    for i in range(n - 1):\n        qc.cry(theta[i],i,i + 1)\n        qc.cx(i + 1,i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 1, "result": "RE", "execution_time": "1288 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        theta = math.atan(math.sqrt(i-1))\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n        \n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 2, "result": "RE", "execution_time": "1369 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        theta = math.atan(math.sqrt(i-1))\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 3, "result": "RE", "execution_time": "1407 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-3):\n        theta = math.atan(math.sqrt(i-1))\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 4, "result": "RE", "execution_time": "1496 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        x = math.sqrt(i-1)\n        theta = math.atan(x)\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 5, "result": "RE", "execution_time": "1193 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        x = math.sqrt(i-1)\n        theta = math.atan(x)\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 6, "result": "RE", "execution_time": "1438 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        x = math.sqrt(i-1)\n        theta = math.atan(x)\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 7, "result": "WA", "execution_time": "1279 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        x = math.sqrt(i+1)\n        theta = math.atan(x)\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 8, "result": "WA", "execution_time": "1566 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        x = math.sqrt(i+2)\n        theta = math.atan(x)\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 9, "result": "WA", "execution_time": "1328 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        x = math.sqrt(n-i-2)\n        theta = math.atan(x)\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AE8A7BD837AD3", "submission_order": 10, "result": "WA", "execution_time": "1843 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        x = math.sqrt(n-i-1)\n        theta = math.atan(x)\n        qc.ry(theta,i)\n        qc.ch(i,i+1)\n        qc.ccx(i,i+1,i+2)\n        qc.cx(i,i+1)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AF65A6F11110E", "submission_order": 1, "result": "RE", "execution_time": "1205 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n):\n        theta = 2*math.acos(math.sqrt(1/(n-i)))\n        qc.cry(theta, 0, i+1)\n        qc.cx(i+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AF65A6F11110E", "submission_order": 2, "result": "RE", "execution_time": "1184 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = 2*math.acos(math.sqrt(1/(n-i)))\n        qc.cry(theta, 0, i+1)\n        qc.cx(i+1, 0)\n\n    return qc\n\nsolve(3).draw('mpl')\n'''"}
{"problem": "QPC003_A4", "user": "AF65A6F11110E", "submission_order": 3, "result": "WA", "execution_time": "1517 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = 2*math.acos(math.sqrt(1/(n-i)))\n        qc.cry(theta, 0, i+1)\n        qc.cx(i+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AF65A6F11110E", "submission_order": 4, "result": "AC", "execution_time": "2459 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = 2*math.acos(math.sqrt((n-i-1)/(n-i)))\n        qc.cry(theta, 0, i+1)\n        qc.cx(i+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AF9C545534B69", "submission_order": 1, "result": "RE", "execution_time": "1220 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    stheta = 2 * atan(math.sqrt(n-1))\n    qc.ry(stheta,0)\n    for i in range(1,n-1):\n        theta = 2*atan(math.sqrt(n-i-1))\n        qc.cry(theta,i-1,i)\n    #qc.x(n-1)\n    for i in range(1,n):\n        qc.cx(i,i-1)\n    qc.x(n-1)\n    for i in range(0,n-1):\n        qc.cx(i,n-1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AF9C545534B69", "submission_order": 2, "result": "AC", "execution_time": "1962 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    stheta = 2 * math.atan(math.sqrt(n-1))\n    qc.ry(stheta,0)\n    for i in range(1,n-1):\n        theta = 2*math.atan(math.sqrt(n-i-1))\n        qc.cry(theta,i-1,i)\n    #qc.x(n-1)\n    for i in range(1,n):\n        qc.cx(i,i-1)\n    qc.x(n-1)\n    for i in range(0,n-1):\n        qc.cx(i,n-1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AFEFCC0C58121", "submission_order": 1, "result": "WA", "execution_time": "1689 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    import math\n    theta = 2 * math.atan(math.sqrt(2))\n    qc.ry(theta, n - 1)\n    qc.ch(n - 1, 0)\n    for i in range(1, n - 1):\n        qc.x(0)\n        qc.x(n - 1)\n        qc.ccx(0, n - 1, i)\n        qc.x(n - 1)\n        qc.x(0)\n    \n    qc.cx(0, n - 1)\n    return qc\n'''"}
{"problem": "QPC003_A4", "user": "AFF9E567BDD63", "submission_order": 1, "result": "AC", "execution_time": "1776 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    theta = 2 * math.acos(math.sqrt(1/n))\n    qc.ry(theta, 0)\n    for i in range(1, n):\n        theta_i = 2 * math.acos(math.sqrt(1/(n-i)))        \n        qc.cry(theta_i, i-1, i)   \n        qc.cx(i, i-1)    \n    for i in range(0, n-1):\n        qc.cx(i, n-1)\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A0742154F0796", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    levels = int(np.ceil(np.log2(n)))\n    qc.x(0)\n\n    box = [0 for _ in range(n)]\n    box[0] = n\n\n    for level in range(levels):\n        tmp = 2**level\n        for i in range(tmp):\n            parent = box[i]\n            if parent == 1:\n                continue\n\n            left = parent//2\n            right = parent - left\n\n            prob_amp = np.sqrt(left / parent)\n            rot_ang = 2 * np.arccos(prob_amp)\n\n            for j in range(tmp, n):\n                if box[j] == 0:\n                    bridge = j\n                    break\n\n            qc.cry(rot_ang, i, bridge)\n            qc.cx(bridge, i)\n\n            box[i] = left\n            box[bridge] = right\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A0A6A62394A14", "submission_order": 1, "result": "AC", "execution_time": "1812 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, acos, sqrt\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(0)\n    def f(l: int, r: int) -> None:\n        if r - l == 1:\n            return\n        mid = (l + r) // 2\n        qc.cry(2 * acos(sqrt((mid-l)/(r-l))), l, mid)\n        qc.cx(mid, l)\n        f(l, mid)\n        f(mid, r)\n    f(0, n)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A0B68F33E8DAA", "submission_order": 1, "result": "WA", "execution_time": "1261 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 9:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    else:\n      qc.ry(2*math.acos(math.sqrt(8.0/n)), 0)\n      qc.cx(0, 8)\n      qc.x(0)\n      for i in range(7):\n        qc.cry(2*math.acos(1.0/math.sqrt(8-i-1)), i, i+1)\n      for i in range(7):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A0B68F33E8DAA", "submission_order": 2, "result": "AC", "execution_time": "1794 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 9:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    else:\n      qc.ry(2*math.acos(math.sqrt(8.0/n)), 0)\n      qc.cx(0, 8)\n      qc.x(0)\n      for i in range(7):\n        qc.cry(2*math.acos(1.0/math.sqrt(8-i)), i, i+1)\n      for i in range(7):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A0C146C4C16DB", "submission_order": 1, "result": "WA", "execution_time": "1447 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.x(i)\n    theta = math.acos(math.sqrt((n-1)/(n))) * 2\n    qc.ry(theta, 0)\n    for i in range(1, n-1):\n        theta = math.acos(math.sqrt((n-i-1)/(n-i))) * 2\n        qc.append(RYGate(theta).control(i), [_ for _ in range(i + 1)])\n    qc.mcx([_ for _ in range(n - 1)], n - 1)\n    for i in range(n-1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A0C146C4C16DB", "submission_order": 2, "result": "AC", "execution_time": "2384 ms", "memory": "168 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.x(i)\n    theta = math.acos(math.sqrt((n-1)/(n))) * 2\n    qc.ry(theta, 0)\n    for i in range(1, n-1):\n        theta = math.acos(math.sqrt((n-i-1)/(n-i))) * 2\n        qc.append(RYGate(theta).control(i), [_ for _ in range(i + 1)])\n    qc.mcx([_ for _ in range(n - 1)], n - 1)\n    for i in range(n-1):\n        qc.x(i)\n    qc.z(n - 1)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A1410382A709B", "submission_order": 1, "result": "AC", "execution_time": "1857 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    split(qc, 0, n)\n\n    return qc\n\ndef split(qc, stIncl, edExcl):\n    if stIncl + 1 == edExcl:\n        return\n\n    mid = (stIncl + edExcl) // 2\n    left = mid - stIncl\n    right = edExcl - mid\n    print(f'{left=} {right=}')\n\n    angle = 2*math.atan(math.sqrt(right/left))\n    qc.cry(angle, stIncl, mid)\n    qc.cx(mid, stIncl)\n\n    split(qc, stIncl, mid)\n    split(qc, mid, edExcl)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A171D56FF5B31", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(1, n):\n        qc.cry(2 * math.acos(1.0 / math.sqrt(n - i + 1)), i - 1, i)\n    \n    for i in range(1, n):\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A2B4A0E7BA686", "submission_order": 1, "result": "DLE", "execution_time": "1272 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n==2:\n        qc.h(0)\n        qc.x(0)\n        qc.cx(0,1)\n        qc.x(0)\n        return qc\n    else:\n        qc.x(0)\n        angle = [0] * (n+1)\n\n        for i in range(n+1):\n            if i==0:\n                pass\n            else:\n                angle[i]=np.arccos(1/np.sqrt(i))\n\n        for i in range(n-2):\n            qc.cry(angle[n-i]*2,i,i+1)\n\n        qc.cx(n-2,n-3)\n        qc.ch(n-2,n-1)\n        qc.cx(n-1,n-2)\n\n        for i in range(n+1):\n            if i<4:\n                pass\n            else:\n                for j in range(i-1):\n                    qc.cx(n-1-j,n-i)\n        return qc\n'''"}
{"problem": "QPC003_A5", "user": "A2BCB8A8E592E", "submission_order": 1, "result": "AC", "execution_time": "1997 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1,0,-1)]\n    for i in range(n - 1):\n        qc.cry(theta[i],i,i + 1)\n    for i in range(n - 1):\n        qc.cx(i + 1,i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A3161250CE9FE", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimpoort math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n    # 各量子ビットに対して重ね合わせを作成\n    for i in range(n):\n        # 回転角度を計算 (θ = 2 * arcsin(1/sqrt(n)))\n        theta = 2 * math.asin(1 / math.sqrt(n))\n        qc.ry(theta, i)\n    \n    # 全ての量子ビットに制御をかけてエンタングルメントを作成\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A37EDED23060F", "submission_order": 1, "result": "DLE", "execution_time": "1278 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos(1/n**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        #前側0をすべて1に\n        for j in range(i):\n            qc.x(j)\n        theta = 2*calc(n-i)\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n            qc.mcx(list(range(i)), i)\n        else:\n            qc.ry(theta, 0)\n            qc.x(0)\n\n        #0->1にしてたやつを戻す\n        for j in range(i):\n            qc.x(j)\n    for i in range(n-1):\n        qc.x(i)\n    qc.mcx(list(range(n-1)), n-1)\n    for i in range(n-1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A37EDED23060F", "submission_order": 2, "result": "DLE", "execution_time": "1718 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos(((n-1)/n)**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        #前側0をすべて1に\n        theta = 2*calc(n-i)\n        #print(\"theta\", theta, math.cos(theta/2))\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n        else:\n            qc.ry(theta, 0)\n        qc.x(i)\n\n    qc.mcx(list(range(n-1)), n-1)\n\n    for i in range(n-1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A37EDED23060F", "submission_order": 3, "result": "DLE", "execution_time": "1750 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nimport math\n\ndef calc(n):\n    return math.acos((1/n)**(1/2))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        #前側0をすべて1に\n        theta = 2*calc(n-i)\n        #print(\"theta\", theta, math.cos(theta/2))\n        if i >= 1:\n            ccry = RYGate(theta).control(num_ctrl_qubits=i, label=None)\n            #qc.mcry(theta, list(range(i)), i)\n            qc.append(ccry, list(range(i+1)))\n        else:\n            qc.ry(theta, 0)\n\n    for i in range(n-1):\n        qc.mcx(list(range(n-i-1)), n-i-1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A4517D12E02DF", "submission_order": 1, "result": "DLE", "execution_time": "1663 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc_w = QuantumCircuit(n)\n    # Write your code here:\n    \n    prob_amp = np.sqrt(1/n)\n    rot_ang = 2*np.arccos(prob_amp)\n    \n    qc_w = QuantumCircuit(n) \n    \n    # probability redistribution\n    qc_w.ry(rot_ang,0)\n    \n    for i in range(1,n-1):\n        comp_amp = np.sqrt(1-i/n)\n        rot_ang = 2*np.arccos(prob_amp/(comp_amp))\n        qc_w.cry(rot_ang,i-1,i)\n    \n    # state reshuffling\n    for i in range(n-1, 0, -1):\n        qc_w.cx(i-1,i)\n    \n    qc_w.x(0)\n    \n    return qc_w\n'''"}
{"problem": "QPC003_A5", "user": "A4517D12E02DF", "submission_order": 2, "result": "WA", "execution_time": "1373 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc_w = QuantumCircuit(n)\n    \n    # Define the target amplitude and initial rotation angle\n    prob_amp = np.sqrt(1 / n)\n    initial_rot_ang = 2 * np.arccos(prob_amp)\n\n    # Start with an X gate on the first qubit (initial step remains the same)\n    qc_w.x(0)\n\n    # Apply controlled rotations in parallel stages to reduce depth\n    for stage in range(0, n-1, 2):\n        # Controlled rotation for even indexed pairs\n        if stage < n - 1:\n            comp_amp = np.sqrt(1 - stage / n)\n            rot_ang = 2 * np.arccos(prob_amp / comp_amp)\n            qc_w.cry(rot_ang, stage, stage + 1)\n            qc_w.cx(stage + 1, stage)\n\n    for stage in range(1, n-1, 2):\n        # Controlled rotation for odd indexed pairs\n        if stage < n - 1:\n            comp_amp = np.sqrt(1 - stage / n)\n            rot_ang = 2 * np.arccos(prob_amp / comp_amp)\n            qc_w.cry(rot_ang, stage, stage + 1)\n            qc_w.cx(stage + 1, stage)\n\n    return qc_w\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 1, "result": "RE", "execution_time": "1284 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    prob_amp = np.sqrt(1 / n)\n    rot_ang = 2 * np.arccos(prob_amp)\n\n    qc.x(0)\n\n    for i in range(n - 1):\n        comp_amp = np.sqrt(1 - i / n)\n        rot_ang = 2 * np.arccos(prob_amp / (comp_amp))\n        qc.cry(rot_ang, i, i + 1)\n        qc_.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 2, "result": "DLE", "execution_time": "1617 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    prob_amp = np.sqrt(1 / n)\n\n    qc.x(0)\n\n    for i in range(n - 1):\n        comp_amp = np.sqrt(1 - i / n)\n        rot_ang = 2 * np.arccos(prob_amp / (comp_amp))\n        qc.cry(rot_ang, i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 3, "result": "WA", "execution_time": "1690 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef apply_w_state(qc, qubits):\n    # ベースケース: 1量子ビットの場合、初期状態 |1> を作成\n    if len(qubits) == 1:\n        qc.x(qubits[0])\n        return\n\n    # 左右に分割\n    mid = len(qubits) // 2\n    left = qubits[:mid]\n    right = qubits[mid:]\n\n    # 左側の状態を|1>と|0>の重ね合わせに回転\n    theta = 2 * np.arccos(np.sqrt(len(left) / len(qubits)))\n    qc.ry(theta, left[0])\n    qc.cx(left[0], right[0])\n\n    # 再帰的に左右に対してW状態を構築\n    apply_w_state(qc, left)\n    apply_w_state(qc, right)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qubits = list(range(n))\n    apply_w_state(qc, qubits)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 4, "result": "WA", "execution_time": "1274 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    prob_amp = np.sqrt(1 / n)\n    rot_ang = 2 * np.arccos(prob_amp)\n\n    qc.x(0)\n\n    def dichotomy_tree(qc, start, size):\n        if size == 1:\n            return\n        left_size = size // 2\n        right_size = size - left_size\n\n        qc.cry(2 * np.arccos(np.sqrt(left_size / size)), start, start + left_size)\n\n        dichotomy_tree(qc, start, left_size)\n        dichotomy_tree(qc, start + left_size, right_size)\n\n    dichotomy_tree(qc, 0, n)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 5, "result": "WA", "execution_time": "1555 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    def dichotomy_tree(qc, start, size):\n        if size == 1:\n            return\n        left_size = size // 2\n        right_size = size - left_size\n\n        qc.cry(2 * np.arccos(np.sqrt(left_size / size)), start, start + left_size)\n\n        dichotomy_tree(qc, start, left_size)\n        dichotomy_tree(qc, start + left_size, right_size)\n\n    dichotomy_tree(qc, 0, n)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 6, "result": "WA", "execution_time": "1346 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    levels = int(np.ceil(np.log2(n)))\n    for level in range(levels):\n        step = 2 ** level\n        for i in range(0, n - step, 2 * step):\n            if i + step < n:\n                qc.cry(2 * np.arccos(1 / np.sqrt(2)), i, i + step)\n                qc.cx(i, i + step)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 7, "result": "WA", "execution_time": "1222 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    levels = int(np.ceil(np.log2(n)))\n    qc.h(0)\n\n    for level in range(levels):\n        step = 2 ** level\n        for i in range(0, n - step, 2 * step):\n            if i + step < n:\n                theta = 2 * np.arccos(1 / np.sqrt(level + 2))\n                qc.cry(theta, i, i + step)\n                qc.cx(i, i + step)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 8, "result": "WA", "execution_time": "1540 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    levels = int(np.ceil(np.log2(n)))\n    qc.h(0)\n\n    for level in range(levels):\n        step = 2 ** level\n        for i in range(0, n - step, 2 * step):\n            if i + step < n:\n                theta = 2 * np.arccos(1 / np.sqrt(level + 2))\n                qc.cry(theta, i, i + step)\n                qc.cx(i + step, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A49EA1B26A21F", "submission_order": 9, "result": "AC", "execution_time": "1955 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    levels = int(np.ceil(np.log2(n)))\n    qc.x(0)\n\n    box = [0 for _ in range(n)]\n    box[0] = n\n\n    for level in range(levels):\n        tmp = 2**level\n        for i in range(tmp):\n            parent = box[i]\n            if parent == 1:\n                continue\n            left = parent//2\n            right = parent - left\n            prob_amp = np.sqrt(left / parent)\n            rot_ang = 2 * np.arccos(prob_amp)\n            for j in range(tmp, n):\n                if box[j] == 0:\n                    bridge = j\n                    break\n            qc.cry(rot_ang, i, bridge)\n            qc.cx(bridge, i)\n            box[i] = left\n            box[bridge] = right\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A5157C5C7E75F", "submission_order": 1, "result": "RE", "execution_time": "1450 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumCircuit\nimport math\n\n\ndef F_gate(circ,q,i,j,n,k) :\n    theta = math.acos(math.sqrt(1/(n-k+1)))\n    circ.ry(-theta,q[j])       \n    circ.cz(q[i],q[j])\n    circ.ry(theta,q[j])\n    circ.barrier(q[i])\n\ndef  cxrv(circ,q,i,j) :\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.cx(q[j],q[i])\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.barrier(q[i],q[j])\n\ndef solve(n: int) -> QuantumCircuit:\n    q = QuantumRegister(n)\n    qc = QuantumCircuit(q)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(1, n):\n        F_gate(qc, q, n-i, n-i-1, n, i)\n    for i in range(1, n):\n        cxrv(qc, q, n-i-1, n-i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A5157C5C7E75F", "submission_order": 2, "result": "RE", "execution_time": "1276 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumCircuit\nimport math\n\n\ndef F_gate(circ,q,i,j,n,k) :\n    theta = math.acos(math.sqrt(1/(n-k+1)))\n    circ.ry(-theta,q[j])       \n    circ.cz(q[i],q[j])\n    circ.ry(theta,q[j])\n    circ.barrier(q[i])\n\ndef  cxrv(circ,q,i,j) :\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.cx(q[j],q[i])\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.barrier(q[i],q[j])\n\ndef solve(n: int) -> QuantumCircuit:\n    q = QuantumRegister(n)\n    qc = QuantumCircuit(q)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(1, n):\n        F_gate(qc, q, n-i, n-i-1, n, i)\n    for i in range(1, n):\n        cxrv(qc, q, n-i-1, n-i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A5157C5C7E75F", "submission_order": 3, "result": "DLE", "execution_time": "1686 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef F_gate(circ,q,i,j,n,k) :\n    theta = math.acos(math.sqrt(1/(n-k+1)))\n    circ.ry(-theta,q[j])       \n    circ.cz(q[i],q[j])\n    circ.ry(theta,q[j])\n    circ.barrier(q[i])\n\ndef  cxrv(circ,q,i,j) :\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.cx(q[j],q[i])\n    circ.h(q[i])\n    circ.h(q[j])\n    circ.barrier(q[i],q[j])\n\ndef solve(n: int) -> QuantumCircuit:\n    q = QuantumRegister(n)\n    qc = QuantumCircuit(q)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(1, n):\n        F_gate(qc, q, n-i, n-i-1, n, i)\n    for i in range(1, n):\n        cxrv(qc, q, n-i-1, n-i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A55D50BE8604C", "submission_order": 1, "result": "DLE", "execution_time": "1343 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(math.asin(1/math.sqrt(n))*2, 0)\n    for i in range(1, n):\n        for j in range(i):\n            qc.x(j)\n        qc.append(RYGate(math.asin(1/math.sqrt(n-i))*2).control(i), range(i+1))\n        for j in range(i):\n            qc.x(j)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_A5", "user": "A55D50BE8604C", "submission_order": 2, "result": "AC", "execution_time": "2083 ms", "memory": "167 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import RYGate, ZGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.ry(math.asin(-1/math.sqrt(n))*2, 0)\n    for i in range(1, n-1):\n        qc.append(RYGate(math.asin(-1/math.sqrt(n-i))*2).control(i), range(i+1))\n    qc.mcx(list(range(n-1)), n-1)\n    for i in range(n):\n        qc.x(i)\n    # print(qc.depth())\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(10)\n    #print(Statevector(qc))\n'''"}
{"problem": "QPC003_A5", "user": "A5B34E91D0B90", "submission_order": 1, "result": "DLE", "execution_time": "1483 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        theta = math.atan(math.sqrt(n-i))*2\n        qc.cry(theta, i-1, i)\n        qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A5B34E91D0B90", "submission_order": 2, "result": "RE", "execution_time": "1194 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    if 8 < n:\n        theta = math.atan(math.sqrt((n-8)/(8)))*2\n        qc.cry(theta, 0, 8)\n        qc.cx(8, 0)\n    if 12 < n:\n        theta = math.atan(math.sqrt((n-12)/(4)))*2\n        qc.cry(theta, 8, 12)\n        qc.cx(12, 8)\n    if 4 < n:\n        theta = math.atan(math.sqrt(min(4,n-4)/(4)))*2\n        qc.cry(theta, 0, 4)\n        qc.cx(4, 0)\n    if 14 < n:\n        theta = math.atan(math.sqrt((n-14)/(2)))*2\n        qc.cry(theta, 12, 14)\n        qc.cx(14, 12)\n    if 10 < n:\n        theta = math.atan(math.sqrt(min(2,n-10)/(2)))*2\n        qc.cry(theta, 8, 10)\n        qc.cx(10, 8)\n    if 6 < n:\n        theta = math.atan(math.sqrt(min(2,n-6)/(2)))*2\n        qc.cry(theta, 4, 6)\n        qc.cx(6, 4)\n    if 2 < n:\n        theta = math.atan(math.sqrt(min(2,n-2)/(2)))*2\n        qc.cry(theta, 0, 2)\n        qc.cx(2, 0)\n    for i in range(1,15,2):\n        if i < n:\n            theta = math.atan(1)*2\n            qc.cry(theta, i-1, i)\n            qc.cx(i-1, i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A5B34E91D0B90", "submission_order": 3, "result": "WA", "execution_time": "1272 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    if 8 < n:\n        theta = math.atan(math.sqrt((n-8)/(8)))*2\n        qc.cry(theta, 0, 8)\n        qc.cx(8, 0)\n    if 12 < n:\n        theta = math.atan(math.sqrt((n-12)/(4)))*2\n        qc.cry(theta, 8, 12)\n        qc.cx(12, 8)\n    if 4 < n:\n        theta = math.atan(math.sqrt(min(4,n-4)/(4)))*2\n        qc.cry(theta, 0, 4)\n        qc.cx(4, 0)\n    if 14 < n:\n        theta = math.atan(math.sqrt((n-14)/(2)))*2\n        qc.cry(theta, 12, 14)\n        qc.cx(14, 12)\n    if 10 < n:\n        theta = math.atan(math.sqrt(min(2,n-10)/(2)))*2\n        qc.cry(theta, 8, 10)\n        qc.cx(10, 8)\n    if 6 < n:\n        theta = math.atan(math.sqrt(min(2,n-6)/(2)))*2\n        qc.cry(theta, 4, 6)\n        qc.cx(6, 4)\n    if 2 < n:\n        theta = math.atan(math.sqrt(min(2,n-2)/(2)))*2\n        qc.cry(theta, 0, 2)\n        qc.cx(2, 0)\n    for i in range(1,15,2):\n        if i < n:\n            theta = math.atan(1)*2\n            qc.cry(theta, i-1, i)\n            qc.cx(i-1, i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A5B34E91D0B90", "submission_order": 4, "result": "AC", "execution_time": "1698 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i,j in [(0,8),(0,4),(8,12),(0,2),(4,6),(8,10),(12,14),(0,1),(2,3),(4,5),(6,7),(8,9),(10,11),(12,13)]:\n        if j >= n:\n            continue\n        theta = math.atan(math.sqrt(min(j-i,n-j)/(j-i)))*2\n        qc.cry(theta, i, j)\n        qc.cx(j,i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A5CAE30AFE39D", "submission_order": 1, "result": "DLE", "execution_time": "1381 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, pi, sqrt\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n - 1):\n        theta = 2 * acos(1 / sqrt(n - i))\n        qc.cry(theta, i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A5CAE30AFE39D", "submission_order": 2, "result": "AC", "execution_time": "1832 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, pi, sqrt\n\ndef func(qc, l:int, r:int) -> QuantumCircuit:\n    m = (l + r) // 2\n    theta = 2 * acos(sqrt((m - l)/(r - l)))\n    qc.cry(theta, l, m)\n    qc.cx(m, l)\n    if m - l > 1:\n        func(qc, l, m)\n    if r - m > 1:\n         func(qc, m, r)\n\n    return qc\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    func(qc, 0, n)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A61E4B079F04A", "submission_order": 1, "result": "AC", "execution_time": "1900 ms", "memory": "158 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(k: int) -> float:\n    return math.asin(math.sqrt((k-1)/k)) * 2\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.cry(theta(n), 0, 1)\n    for i in range(2, n):\n        qc.cry(theta(n-i+1), i-1, i)\n        qc.cx(i-1, i-2)\n    qc.cx(n-1, n-2)\n    return qc\n\n\nif __name__ == \"__main__\":\n    qc = solve(2)\n    print(qc)\n'''"}
{"problem": "QPC003_A5", "user": "A634BD8F0AF99", "submission_order": 1, "result": "AC", "execution_time": "1868 ms", "memory": "157 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    acos,\n    # atan2,\n    sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.cry(asin(sqrt((n - i) / (n - i + 1))) * 2, i - 1, i)\n    for i in range(1, n):\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A63A0F81DE810", "submission_order": 1, "result": "RE", "execution_time": "1273 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(4)  # We need 4 qubits for this state\n\n    # Calculate the rotation angle for the initial Ry gate\n    theta = 4 * math.atan(math.sqrt(6) / (3 + math.sqrt(3)))\n\n    # Apply the RY rotation to the first qubit\n    qc.ry(theta, 0)\n    \n    # Apply controlled-Hadamard (CH) gates to create superposition\n    qc.ch(0, 1)  # Control from qubit 0 to 1\n    qc.cx(1, 0)\n    qc.ch(1, 2)  # Control from qubit 1 to 2\n    qc.cx(2, 1)\n    qc.ch(2, 3)  # Control from qubit 2 to 3\n    qc.cx(3, 2)\n\n    # Apply X gates to prepare for the multi-control Toffoli gate (CCX)\n    qc.x(0)\n    qc.x(1)\n    qc.x(2)\n\n    # Apply Toffoli gate to flip the last qubit if the first three are all |1>\n    qc.mcx([0, 1, 2], 3)  # Multi-controlled X gate (CCX equivalent for 3 controls)\n\n    # Revert the X gates to return the state to the desired form\n    qc.x(0)\n    qc.x(1)\n    qc.x(2)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A63A0F81DE810", "submission_order": 2, "result": "AC", "execution_time": "2151 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n \n    count = 1\n \n    # queue = [(a, b, control bit of CRy), ...]\n    queue = [(n // 2, n, 0)]\n \n    # breadth first search\n    while len(queue):\n        a, b, control = queue.pop(0)\n \n        if a == 0:\n            continue\n \n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n \n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n \n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n \n        count += 1\n \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A66811ABEB37E", "submission_order": 1, "result": "AC", "execution_time": "2031 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import asin\n\n\ndef move(qc, f, t, ratio):\n    theta = 2 * asin(ratio**0.5)\n    qc.cry(theta, f, t)\n    qc.cx(t, f)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    parent = [None]\n    for i in range(1, n):\n        for r in (8, 4, 2, 1):\n            if i & r:\n                parent.append(i - r)\n                break\n\n    # print(parent)\n\n    ww = [0] * n\n    for i in range(n - 1, -1, -1):\n        ww[i] += 1 / n\n        if parent[i] is not None:\n            ww[parent[i]] += ww[i]\n\n    # print(ww)\n\n    xx = [0] * n\n    xx[0] = 1\n\n    for i in range(1, n):\n        p = parent[i]\n        move(qc, p, i, ww[i] / xx[p])\n        xx[p] -= ww[i]\n        xx[i] = ww[i]\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A69205611E16C", "submission_order": 1, "result": "AC", "execution_time": "2420 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(n - 1):\n        qc.cry(2 * math.atan(math.sqrt(n - _ - 1)), _, _ + 1)\n    for _ in range(n - 1):\n        qc.cx(_ + 1, _)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A76FA11C8AF5C", "submission_order": 1, "result": "WA", "execution_time": "1464 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nimport numpy\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(n - 1):\n        theta = 2 * numpy.arccos(math.sqrt(1/(n - i)))\n        qc.cry(theta, i, i + 1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A76FA11C8AF5C", "submission_order": 2, "result": "AC", "execution_time": "1840 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\nimport numpy\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(n - 1):\n        theta = 2 * numpy.arccos(math.sqrt(1/(n - i)))\n        qc.cry(theta, i, i + 1)\n    \n    for i in range(n - 1):\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A7BA70B0EC583", "submission_order": 1, "result": "WA", "execution_time": "1817 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard to the first qubit\n    qc.h(0)\n    \n    # Step 2: Apply CNOT gates to create the desired superposition\n    for i in range(1, n):\n        qc.cx(0, i)  # CNOT from qubit 0 to qubit i\n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A80E3DB136FA3", "submission_order": 1, "result": "DLE", "execution_time": "1479 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * math.atan(math.sqrt(n-1))\n    qc.ry(theta,0)\n    \n    for i in range(n-2):\n        theta = 2 * math.atan(math.sqrt(n-i-2))\n        qc.cry(theta,i,i+1)\n    \n    qc.cx(n-2,n-1)\n    for i in range(n-2)[::-1]:\n        qc.cx(i,i+1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A80E3DB136FA3", "submission_order": 2, "result": "RE", "execution_time": "1657 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #l,rに分ける\n    u = n//2\n    l = (n+1)//2\n    theta = 2 * math.atan(math.sqrt(u)/math.sqrt(l))\n    qc.ry(theta,l)\n    \n    #u側\n    theta = 2 * math.atan(math.sqrt(u-2))\n    qc.cry(theta,l,l+1)\n    qc.x(l)\n    qc.cx(l,0)\n\n    #u側\n    for i in range(1,u-2):\n        theta = 2 * math.atan(math.sqrt(u-i-2))\n        qc.cry(theta,l+i,l+i+1)\n\n    qc.cx(n-2,n-1)\n    for i in range(n-2)[::-1]:\n        qc.cx(i,i+1)\n    \n    #l側\n    for i in range(l-2):\n        theta = 2 * math.atan(math.sqrt(l-i-2))\n        qc.cry(theta,i,i+1)\n    \n    qc.cx(l-2,l-1)\n    for i in range(l-2)[::-1]:\n        qc.cx(i,i+1)\n\n    qc.x(l)\n\n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A80E3DB136FA3", "submission_order": 3, "result": "RE", "execution_time": "2071 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    #l,rに分ける\n    u = n//2\n    l = (n+1)//2\n    theta = 2 * math.atan(math.sqrt(u)/math.sqrt(l))\n    qc.ry(theta,l)\n    \n    #u側\n    theta = 2 * math.atan(math.sqrt(u-2))\n    qc.cry(theta,l,l+1)\n    qc.x(l)\n    qc.cx(l,0)\n\n    #u側\n    for i in range(1,u-2):\n        theta = 2 * math.atan(math.sqrt(u-i-2))\n        qc.cry(theta,l+i,l+i+1)\n\n    qc.cx(n-2,n-1)\n    for i in range(u-2)[::-1]:\n        qc.cx(l+i,l+i+1)\n    \n    #l側\n    for i in range(l-2):\n        theta = 2 * math.atan(math.sqrt(l-i-2))\n        qc.cry(theta,i,i+1)\n    \n    qc.cx(l-2,l-1)\n    for i in range(l-2)[::-1]:\n        qc.cx(i,i+1)\n\n    qc.x(l)\n\n    \n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A89082141F7D2", "submission_order": 1, "result": "DLE", "execution_time": "1502 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    \n    for i in range(n-1):\n        theta = 2 * np.arccos(np.sqrt(1 / (n - i)))\n        qc.cry(theta,i, i+1)    \n        qc.cx(i+1,i)   \n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A89082141F7D2", "submission_order": 2, "result": "WA", "execution_time": "1314 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    \n    for i in range(1, n):\n        theta = 2 * np.arccos(np.sqrt(1 / (i + 1)))\n        qc.cry(theta, i - 1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A89082141F7D2", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom math import ceil,floor,acos,sqrt\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    \n    cnt=1\n    \n    que=[(n,0)]\n\n    while len(que):\n        a,ctrl=que.pop(0)\n        \n        if a == 0 or a==1:\n            continue\n        b=ceil(a/2)\n        c=floor(a/2)\n        t=2*acos(sqrt(b/a))\n        \n        qc.cry(t,ctrl,cnt)\n        qc.cx(cnt,ctrl)\n        \n        if b>1:\n            que.append((b,ctrl))\n        if c>1:\n            que.append((c,cnt))\n        \n        cnt+=1\n        \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A8CD9048711E9", "submission_order": 1, "result": "AC", "execution_time": "2339 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    n0 = n-n//2\n    n1 = n//2\n    qc.cry(2*math.acos(math.sqrt(n0/n)),0,1)\n    qc.cx(1,0)\n    for i in range(n0-1):\n        qc.cry(2*math.acos(1/math.sqrt(n0-i)),2*i, 2*i+2)\n        qc.cx(2*i+2, 2*i)\n    for i in range(n1-1):\n        qc.cry(2*math.acos(1/math.sqrt(n1-i)),2*i+1, 2*i+3)\n        qc.cx(2*i+3, 2*i+1)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "A9C3BED1E36E1", "submission_order": 1, "result": "DLE", "execution_time": "1688 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(2*math.acos(1/math.sqrt(n)),0)\n    for i in range(1,n-1):\n        qc.cry(2*math.acos(1/math.sqrt(n-i)),i-1,i)\n    for i in range(n-1,0,-1):\n        qc.cx(i-1,i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AAD7DFCFBA0B4", "submission_order": 1, "result": "WA", "execution_time": "1237 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, sqrt, atan\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    theta = 2 * atan(sqrt(n - 1))\n    qc.ry(theta, 0)\n\n    for i in range(1, n):\n        theta = 2 * atan(sqrt(n - i - 1))\n        qc.cry(theta, i - 1, i)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AAD7DFCFBA0B4", "submission_order": 2, "result": "RE", "execution_time": "1379 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, sqrt, atan\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.x(0)\n    \n    for i in range(1, n):\n        theta = 2 * acos(1.0 / sqrt(n - i + 1))\n        qc.cry(theta, i - 1, i)\n    \n    \n    for i in range(1, n):\n        qc.cx(i, i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AAD7DFCFBA0B4", "submission_order": 3, "result": "RE", "execution_time": "1117 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math  \n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.x(0)\n    \n    for i in range(1, n):\n        theta = 2 * math.acos(1.0 / sqrt(n - i + 1))\n        qc.cry(theta, i - 1, i)\n    \n    \n    for i in range(1, n):\n        qc.cx(i, i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AAD7DFCFBA0B4", "submission_order": 4, "result": "AC", "execution_time": "1722 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math  \n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.x(0)\n    \n    for i in range(1, n):\n        theta = 2 * math.acos(1.0 / math.sqrt(n - i + 1))\n        qc.cry(theta, i - 1, i)\n    \n    \n    for i in range(1, n):\n        qc.cx(i, i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD035FF3271AE", "submission_order": 1, "result": "AC", "execution_time": "2639 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        theta = 2 * math.atan(math.sqrt(n - i - 1))\n        qc.cry(theta, i, i+1)\n\n    for i in range(n-1):\n        qc.cx(i+1, i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD09D846661CC", "submission_order": 1, "result": "WA", "execution_time": "1355 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n\n    def theta(n: int, m: int) -> float:\n        return 2 * math.acos(math.sqrt(m/n))\n\n    a = 1\n    while a*2 < n:\n        a *= 2\n    \n    qc.x(0)\n    while a > 0:\n        j = 0\n        while j + a < n:\n            # print(j, j+a)\n            qc.cry(theta(min(2*a, n), a), j, j+a)\n            qc.cx(j+a,j)\n            j += a+1\n        a //= 2\n \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD09D846661CC", "submission_order": 2, "result": "WA", "execution_time": "1295 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef theta(n: int, m: int) -> float:\n    return 2 * math.acos(math.sqrt(m/n))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    a = 1\n    while a*2 < n:\n        a *= 2\n    \n    qc.x(0)\n    while a > 0:\n        j = 0\n        while j + a < n:\n            qc.cry(theta(min(2*a, n), a), j, j+a)\n            qc.cx(j+a,j)\n            j += a+1\n        a //= 2\n \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD09D846661CC", "submission_order": 3, "result": "AC", "execution_time": "2303 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef theta(n: int, m: int) -> float:\n    return 2 * math.acos(math.sqrt(m/n))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    a = 1\n    while a*2 < n:\n        a *= 2\n    \n    qc.x(0)\n    while a > 0:\n        j = 0\n        while j + a < n:\n            qc.cry(theta(min(2*a, n-j), a), j, j+a)\n            qc.cx(j+a, j)\n            j += 2*a\n        a //= 2\n \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD82283F3B11A", "submission_order": 1, "result": "DLE", "execution_time": "1220 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = 2*math.acos(math.sqrt((n-i-1)/(n-i)))\n        qc.cry(theta, 0, i+1)\n        qc.cx(i+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD82283F3B11A", "submission_order": 2, "result": "WA", "execution_time": "1275 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n<=9:\n        qc.x(0)\n\n        for i in range(n-1):\n            theta = 2*math.acos(math.sqrt((n-i-1)/(n-i)))\n            qc.cry(theta, 0, i+1)\n            qc.cx(i+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD82283F3B11A", "submission_order": 3, "result": "WA", "execution_time": "1616 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 9:\n        qc.x(0)\n\n        for i in range(n-1):\n            theta = 2*math.acos(math.sqrt((n-i-1)/(n-i)))\n            qc.cry(theta, 0, i+1)\n            qc.cx(i+1, 0)\n    else:\n        qc.x(0)\n        qc.x(n//2)\n\n        for i in range(n//2-1):\n            theta = 2*math.acos(math.sqrt((n-i-1)/(n-i)))\n            qc.cry(theta, 0, i+1)\n            qc.cx(i+1, 0)\n            qc.cx(i+1, n//2)\n\n        for i in range(n//2, n-1):\n            theta = 2*math.acos(math.sqrt((n-i-1)/(n-i)))\n            qc.cry(theta, n//2, i+1)\n            qc.cx(i+1, n//2)\n            qc.cx(i+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD82283F3B11A", "submission_order": 4, "result": "WA", "execution_time": "1306 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = 2*math.acos(math.sqrt((n-i-1)/(n-i)))\n        qc.cry(theta, 0, i+1)\n    for i in range(n-1):\n        qc.cx(i+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD82283F3B11A", "submission_order": 5, "result": "WA", "execution_time": "1270 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = 2*math.acos(math.sqrt((n-i-1)/(n-i)))\n        qc.cry(theta, i, i+1)\n    for i in range(n-1):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AD82283F3B11A", "submission_order": 6, "result": "RE", "execution_time": "1248 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = 2*math.acos(math.sqrt(1/n-i))\n        qc.cry(theta, i, i+1)\n    for i in range(n-1):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "ADD2EA67A3090", "submission_order": 1, "result": "WA", "execution_time": "1398 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(n-1):\n        theta = 2 * math.acos((n-i)**-0.5)\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AE12D1828E8E7", "submission_order": 1, "result": "RE", "execution_time": "1921 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)    \n\n    for i in range(0, n-1):\n        theta = math.atan(math.sqrt(n-i-1)) * 2\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AE12D1828E8E7", "submission_order": 2, "result": "DLE", "execution_time": "2093 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # theta = []\n    # for i in range(n-1):\n    #     theta.append(math.atan(math.sqrt(n-i-1))*2)\n\n\n    qc.x(0)    \n\n    for i in range(0, n-1):\n        theta = math.atan(math.sqrt(n-i-1)) * 2\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AE12D1828E8E7", "submission_order": 3, "result": "DLE", "execution_time": "1865 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = math.atan(math.sqrt(n-1-i)) * 2\n        qc.cry(theta, i, i+1)\n        qc.cx(i+1, i)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AE12D1828E8E7", "submission_order": 4, "result": "AC", "execution_time": "1840 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(n-1):\n        theta = math.atan(math.sqrt(n-1-i)) * 2\n        qc.cry(theta, i, i+1)\n    \n    for i in range(n-1):\n\n        qc.cx(i+1, i)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AE46E156EE2BF", "submission_order": 1, "result": "AC", "execution_time": "1934 ms", "memory": "158 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)]\n \n    qc.x(0)\n \n    for i in range(n-1):\n        qc.cry(theta[i], i, i + 1)\n        \n    for i in range(n - 1):\n        \n        qc.cx(i + 1, i)\n \n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AE5E2217EF5B3", "submission_order": 1, "result": "RE", "execution_time": "1476 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)]\n    qc.x(0)\n    for i in range(n - 1):\n        qc.cry(theta[i], i, i + 1)\n    for i in range(n - 1):\n        qc.cx(i + 1,i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AE5E2217EF5B3", "submission_order": 2, "result": "AC", "execution_time": "2083 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = [2 * math.atan(math.sqrt(i)) for i in range(n - 1, 0, -1)]\n    qc.x(0)\n    for i in range(n - 1):\n        qc.cry(theta[i], i, i + 1)\n    for i in range(n - 1):\n        qc.cx(i + 1,i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AED641CB08B79", "submission_order": 1, "result": "AC", "execution_time": "1961 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.x(0)\n\n\tdef solve_for(l, r):\n\t\tif r - l == 1:\n\t\t\treturn\n\t\tm = l + r >> 1\n\t\ttheta = 2 * acos(sqrt(m - l) / sqrt(r - l))\n\t\tqc.cry(theta, l, m)\n\t\tqc.cx(m, l)\n\t\tsolve_for(l, m)\n\t\tsolve_for(m, r)\n\n\tsolve_for(0, n)\n\treturn qc\n'''"}
{"problem": "QPC003_A5", "user": "AF2DC2FEC97D3", "submission_order": 1, "result": "RE", "execution_time": "1227 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)]\n    qc.x(0)\n    for i in range(n-1):\n        qc.cry(theta[i],i,i+1)\n        qc.cx(i+1,i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AF2DC2FEC97D3", "submission_order": 2, "result": "DLE", "execution_time": "1611 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)]\n    qc.x(0)\n    for i in range(n-1):\n        qc.cry(theta[i],i,i+1)\n        qc.cx(i+1,i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AF2DC2FEC97D3", "submission_order": 3, "result": "AC", "execution_time": "1615 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta=[2*math.atan(math.sqrt(i)) for i in range(n-1,0,-1)]\n    qc.x(0)\n    for i in range(n-1):\n        qc.cry(theta[i],i,i+1)\n    for i in range(n-1):\n        qc.cx(i+1,i)\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AF468BBCA492E", "submission_order": 1, "result": "AC", "execution_time": "1763 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range( n - 1 ):\n        x =  math.sqrt(1/ (n-i))\n        y =  math.sqrt((n-i-1)/(n-i))\n        theta = 2 * math.atan(y/x)\n        if i == 0:\n            qc.ry(theta, i)\n        else:\n            qc.cry(theta, i-1, i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-2):\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AF7A7E7011860", "submission_order": 1, "result": "RE", "execution_time": "1217 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ry(2*math.arccos(1/math.sqrt(n)))\n    for target in range(1, n-1):\n        qc.ch(target-1, target)\n\n    for target in range(n-1, 0, -1):\n        qc.cx(target-1, target)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_A5", "user": "AF7A7E7011860", "submission_order": 2, "result": "RE", "execution_time": "1395 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ry(2*math.acos(1/math.sqrt(n)), 0)\n    for target in range(1, n-1):\n        qc.ch(target-1, target)\n\n    for target in range(n-1, 0, -1):\n        qc.cx(target-1, target)\n    qc.x(0)\n'''"}
{"problem": "QPC003_A5", "user": "AF7A7E7011860", "submission_order": 3, "result": "WA", "execution_time": "1655 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.ry(2*math.acos(1/math.sqrt(n)), 0)\n    for target in range(1, n-1):\n        qc.ch(target-1, target)\n\n    for target in range(n-1, 0, -1):\n        qc.cx(target-1, target)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A06D65F8EEDB4", "submission_order": 1, "result": "WA", "execution_time": "1291 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Hゲートを各量子ビットに適用して、均等な重ね合わせを作成\n    for i in range(n):\n        qc.h(i)\n\n    # 各量子ビットが1つだけ1となる状態の測定を行う\n    return qc\n\n# n の値を指定\nn = 4  # 例として n = 4 の場合\nqc = solve(n)\n'''"}
{"problem": "QPC003_A6", "user": "A1083088BF7F0", "submission_order": 1, "result": "AC", "execution_time": "1647 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    a = [[0]*n for _ in range(5)]\n    for i in range(n):\n        a[4][i] = 1\n    for i in range(3, -1, -1):\n        for j in range(n):\n            a[i][j] = a[i+1][j]\n            if j+2**i<n:\n                a[i][j] += a[i+1][j+2**i]\n    for i in range(4):\n        if 2**i>=n:\n            break\n        for j in range(0, 2**i):\n            if j+2**i<n:\n                qc.cry(math.acos(math.sqrt(a[i+1][j]/a[i][j]))*2, j, j+2**i)\n                qc.cx(j+2**i, j)\n    # print(qc.depth())\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(15)\n    #print(Statevector(qc))\n'''"}
{"problem": "QPC003_A6", "user": "A2023E79DE587", "submission_order": 1, "result": "AC", "execution_time": "1898 ms", "memory": "157 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    acos,\n    # atan2,\n    sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef split_state(qc: QuantumCircuit, targets: list[int], proportions: list[float]):\n    sum_p = sum(proportions)\n    proportions = [p / sum_p for p in proportions]\n    for i in range(1, len(targets)):\n        qc.cry(\n            asin(sqrt((1 - sum(proportions[:i])) / (1 - sum(proportions[: i - 1]))))\n            * 2,\n            targets[i - 1],\n            targets[i],\n        )\n    for i in range(1, len(targets)):\n        qc.cx(targets[i], targets[i - 1])\n\n\ndef solve_main(qc: QuantumCircuit, i0: int, i1: int):\n    if i1 - i0 <= 1:\n        return\n    i = (i0 + i1) // 2\n    split_state(qc, [i0, i], [len(range(i0, i)), len(range(i, i1))])\n    solve_main(qc, i0, i)\n    solve_main(qc, i, i1)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    solve_main(qc, 0, n)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A360D33416DD5", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    levels = int(np.ceil(np.log2(n)))\n    qc.x(0)\n\n    box = [0 for _ in range(n)]\n    box[0] = n\n\n    for level in range(levels):\n        tmp = 2**level\n        for i in range(tmp):\n            parent = box[i]\n            if parent == 1:\n                continue\n\n            left = parent//2\n            right = parent - left\n\n            prob_amp = np.sqrt(left / parent)\n            rot_ang = 2 * np.arccos(prob_amp)\n\n            for j in range(tmp, n):\n                if box[j] == 0:\n                    bridge = j\n                    break\n\n            qc.cry(rot_ang, i, bridge)\n            qc.cx(bridge, i)\n\n            box[i] = left\n            box[bridge] = right\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A401D7AC122B3", "submission_order": 1, "result": "AC", "execution_time": "2996 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        print(i,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_A6", "user": "A43AB9FAB5173", "submission_order": 1, "result": "AC", "execution_time": "1832 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import acos, pi, sqrt\n\ndef func(qc, l:int, r:int) -> QuantumCircuit:\n    m = (l + r) // 2\n    theta = 2 * acos(sqrt((m - l)/(r - l)))\n    qc.cry(theta, l, m)\n    qc.cx(m, l)\n    if m - l > 1:\n        func(qc, l, m)\n    if r - m > 1:\n         func(qc, m, r)\n\n    return qc\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    func(qc, 0, n)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A447E8F89BAA6", "submission_order": 1, "result": "AC", "execution_time": "2516 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n\n    count = 1\n\n    # queue = [(a, b, control bit of CRy), ...]\n    queue = [(n // 2, n, 0)]\n\n    # breadth first search\n    while len(queue):\n        a, b, control = queue.pop(0)\n\n        if a == 0:\n            continue\n\n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n\n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n\n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n\n        count += 1\n\n    return qc\n\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n\n#     n = 3\n#     qc = solve(n)\n#     sv = Statevector(qc)\n#     print(sv)\n#     print(qc)\n#     print(f\"{qc.depth() = }\")\n#     # sv = Statevector.from_label('01000')\n#     # print(sv.evolve(qc))\n'''"}
{"problem": "QPC003_A6", "user": "A4CE75FBB8F18", "submission_order": 1, "result": "AC", "execution_time": "1841 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    levels = int(np.ceil(np.log2(n)))\n    qc.x(0)\n\n    box = [0 for _ in range(n)]\n    box[0] = n\n\n    for level in range(levels):\n        tmp = 2**level\n        for i in range(tmp):\n            parent = box[i]\n            if parent == 1:\n                continue\n            left = parent//2\n            right = parent - left\n            prob_amp = np.sqrt(left / parent)\n            rot_ang = 2 * np.arccos(prob_amp)\n            for j in range(tmp, n):\n                if box[j] == 0:\n                    bridge = j\n                    break\n            qc.cry(rot_ang, i, bridge)\n            qc.cx(bridge, i)\n            box[i] = left\n            box[bridge] = right\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A577FE2EE85AA", "submission_order": 1, "result": "AC", "execution_time": "2164 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.x(0)\n\n\tdef solve_for(l, r):\n\t\tif r - l == 1:\n\t\t\treturn\n\t\tm = l + r >> 1\n\t\ttheta = 2 * acos(sqrt(m - l) / sqrt(r - l))\n\t\tqc.cry(theta, l, m)\n\t\tqc.cx(m, l)\n\t\tsolve_for(l, m)\n\t\tsolve_for(m, r)\n\n\tsolve_for(0, n)\n\treturn qc\n'''"}
{"problem": "QPC003_A6", "user": "A5A26A2557EEF", "submission_order": 1, "result": "WA", "execution_time": "1935 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard to the first qubit to create superposition\n    qc.h(0)\n    \n    # Apply controlled NOT gates to create the desired states\n    for i in range(1, n):\n        qc.cx(0, i)  # Control on qubit 0, target on qubit i\n    \n    # Apply a normalization factor (not explicitly in the circuit, but conceptually)\n    # The state is already normalized due to the structure of the circuit.\n    \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A5BB29562F6C5", "submission_order": 1, "result": "AC", "execution_time": "1662 ms", "memory": "157 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n \n    count = 1\n \n    # queue = [(a, b, control bit of CRy), ...]\n    queue = [(n // 2, n, 0)]\n \n    # breadth first search\n    while len(queue):\n        a, b, control = queue.pop(0)\n \n        if a == 0:\n            continue\n \n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n \n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n \n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n \n        count += 1\n \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A87B626930645", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom math import *\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    \n    cnt=1\n    \n    que=[(n,0)]\n\n    while len(que):\n        a,ctrl=que.pop(0)\n        \n        if a == 0 or a==1:\n            continue\n        b=ceil(a/2)\n        c=floor(a/2)\n        t=2*acos(sqrt(b/a))\n        \n        qc.cry(t,ctrl,cnt)\n        qc.cx(cnt,ctrl)\n        \n        que.append((b,ctrl))\n        que.append((c,cnt))\n        \n        cnt+=1\n        \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A87B626930645", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom math import ceil,floor,acos,sqrt\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    \n    cnt=1\n    \n    que=[(n,0)]\n\n    while len(que):\n        a,ctrl=que.pop(0)\n        \n        if a == 0 or a==1:\n            continue\n        b=ceil(a/2)\n        c=floor(a/2)\n        t=2*acos(sqrt(b/a))\n        \n        qc.cry(t,ctrl,cnt)\n        qc.cx(cnt,ctrl)\n        \n        que.append((b,ctrl))\n        que.append((c,cnt))\n        \n        cnt+=1\n        \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A8FBCAE11B4D6", "submission_order": 1, "result": "RE", "execution_time": "1836 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    count = 1\n    queue = [(n//2, n, 0)]\n    while len(queue):\n        a,b,control = queue.pop()\n        if a == 0:\n            continue;\n        qc.cry(2 * math.atan(math.sqrt((b - a) / a)),control,count)\n        qc.cx(count,control)\n        qc.append(((b // 2) // 2,b // 2, control))\n        qc.append((math.ceil(b / 2) // 2,math.ceil(b / 2), count))\n        count += 1\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A8FBCAE11B4D6", "submission_order": 2, "result": "RE", "execution_time": "1443 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    count = 1\n    queue = [(n//2, n, 0)]\n    while len(queue):\n        a,b,control = queue.pop(0)\n        if a == 0:\n            continue;\n        qc.cry(2 * math.atan(math.sqrt((b - a) / a)),control,count)\n        qc.cx(count,control)\n        qc.append(((b // 2) // 2,b // 2, control))\n        qc.append((math.ceil(b / 2) // 2,math.ceil(b / 2), count))\n        count += 1\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A8FBCAE11B4D6", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    count = 1\n    queue = [(n//2, n, 0)]\n    while len(queue):\n        a,b,control = queue.pop(0)\n            continue;\n        if a > 0 and b > a:\n            qc.cry(2 * math.atan(math.sqrt((b - a) / a)),control,count)\n            qc.cx(count,control)\n        if b // 2 > 0:\n            qc.cx(control, count)\n            queue.append(((b // 2) // 2, b // 2, control))\n        if math.ceil(b / 2) // 2 > 0:\n            qc.cx(count, control)\n            queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n        count += 1\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A8FBCAE11B4D6", "submission_order": 4, "result": "WA", "execution_time": "1652 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    count = 1\n    queue = [(n//2, n, 0)]\n    while len(queue):\n        a,b,control = queue.pop(0)\n        if a == 0:\n            continue;\n        if a > 0 and b > a:\n            qc.cry(2 * math.atan(math.sqrt((b - a) / a)),control,count)\n            qc.cx(count,control)\n        if b // 2 > 0:\n            qc.cx(control, count)\n            queue.append(((b // 2) // 2, b // 2, control))\n        if math.ceil(b / 2) // 2 > 0:\n            qc.cx(count, control)\n            queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n        count += 1\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A8FBCAE11B4D6", "submission_order": 5, "result": "AC", "execution_time": "2919 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    count = 1\n    queue = [(n//2, n, 0)]\n    while len(queue):\n        a,b,control = queue.pop(0)\n        if a == 0:\n            continue;\n        qc.cry(2 * math.atan(math.sqrt((b - a) / a)),control,count)\n        qc.cx(count,control)\n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n        count += 1\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A98FFACF6AFED", "submission_order": 1, "result": "WA", "execution_time": "2156 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    keep = [n]\n    qc.x(0)\n    for i in range(int(math.log2(n)) + 1):\n        for j in range(2**i):\n            if 2**i + j < n:\n                x = keep.pop(0)\n                a = (x + 1) // 2\n                b = x // 2\n                keep.append(a)\n                keep.append(b)\n                theta = 2 * math.atan(math.sqrt(b / a))\n                qc.cry(theta, j, j + 2**i)\n            print(keep)\n        for k in range(2**i):\n            if 2 ** i + k < n:\n                qc.cx(k + 2**i, k)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A98FFACF6AFED", "submission_order": 2, "result": "WA", "execution_time": "2525 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    keep = [n]\n    qc.x(0)\n    for i in range(int(math.log2(n)) + 1):\n        for j in range(2**i):\n            if 2**i + j < n:\n                x = keep.pop(0)\n                a = (x + 1) // 2\n                b = x // 2\n                keep.append(a)\n                keep.append(b)\n                theta = 2 * math.atan(math.sqrt(b / a))\n                qc.cry(theta, j, j + 2**i)\n        for k in range(2**i):\n            if 2 ** i + k < n:\n                qc.cx(k + 2**i, k)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A98FFACF6AFED", "submission_order": 3, "result": "WA", "execution_time": "1974 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    keep = [n]\n    qc.x(0)\n    for i in range(int(math.log2(n)) + 1):\n        for j in range(2**i):\n            # print(2**i + j)\n            if 2**i + j < n:\n                x = keep.pop(0)\n                a = (x + 1) // 2\n                b = x // 2\n                if a > 1:\n                    keep.append(a)\n                if b > 1:\n                    keep.append(b)\n                theta = 2 * math.atan(math.sqrt(b / a))\n                qc.cry(theta, j, j + 2**i)\n            \n            # print(keep)\n        for k in range(2**i):\n            if 2 ** i + k < n:\n                qc.cx(k + 2**i, k)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "A98FFACF6AFED", "submission_order": 4, "result": "AC", "execution_time": "2273 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    keep = {0:n}\n    qc.x(0)\n    for i in range(int(math.log2(n)) + 1):\n        for j in range(2**i):\n            # print(2**i + j)\n            if 2**i + j < n:\n                x = keep.pop(j)\n                a = (x + 1) // 2\n                b = x // 2\n                # print(a, b)\n                if a > 1:\n                    keep[j] = a\n                if b > 1:\n                    keep[j + 2**i] = b\n                theta = 2 * math.atan(math.sqrt(b / a))\n                qc.cry(theta, j, j + 2**i)\n            \n            # print(keep)\n        for k in range(2**i):\n            if 2 ** i + k < n:\n                qc.cx(k + 2**i, k)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA0448EDA2336", "submission_order": 1, "result": "DLE", "execution_time": "1701 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range( n - 1 ):\n        x =  math.sqrt(1/ (n-i))\n        y =  math.sqrt((n-i-1)/(n-i))\n        theta = 2 * math.atan(y/x)\n        if i == 0:\n            qc.ry(theta, i)\n        else:\n            qc.cry(theta, i-1, i)\n\n    qc.x(n-1)\n    qc.cx(0,n-1)\n    for i in range(n-2):\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 1, "result": "WA", "execution_time": "1590 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 13:\n      qc.x(0)\n      qc.cry(2*math.acos(math.sqrt(5.0/n)), 0, 5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      for i in range(n-10):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(n-10):\n        qc.cry(-math.pi, i+10, i+9)\n    elif n < 15:\n      qc.x(0)\n      qc.cry(2*math.acos(math.sqrt(5.0/n)), 0, 5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-9))), 9, 12)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(2):\n        qc.cry(-math.pi, i+10, i+9)\n      for i in range(n-13):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-13-i)), i+12, i+13)\n      for i in range(n-13):\n        qc.cry(-math.pi, i+13, i+12)\n    else:\n      qc.x(0)\n      qc.cry(2*math.acos(math.sqrt(5.0/n)), 0, 5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-9))), 9, 12)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(2):\n        qc.cry(-math.pi, i+10, i+9)\n      qc.cry(2*math.acos(math.sqrt(2.0/(n-12))), 12, 14)\n      for i in range(1):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-13-i)), i+12, i+13)\n      for i in range(1):\n        qc.cry(-math.pi, i+13, i+12)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 2, "result": "WA", "execution_time": "1709 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 13:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      for i in range(n-10):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(n-10):\n        qc.cry(-math.pi, i+10, i+9)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-9))), 9, 12)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(2):\n        qc.cry(-math.pi, i+10, i+9)\n      for i in range(n-13):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-13-i)), i+12, i+13)\n      for i in range(n-13):\n        qc.cry(-math.pi, i+13, i+12)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-9))), 9, 12)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(2):\n        qc.cry(-math.pi, i+10, i+9)\n      qc.cry(2*math.acos(math.sqrt(2.0/(n-12))), 12, 14)\n      for i in range(1):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-13-i)), i+12, i+13)\n      for i in range(1):\n        qc.cry(-math.pi, i+13, i+12)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 3, "result": "WA", "execution_time": "1590 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 13:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      qc.cx(9, 5)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      for i in range(n-10):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(n-10):\n        qc.cry(-math.pi, i+10, i+9)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      qc.cx(9, 5)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-9))), 9, 12)\n      qc.cx(12, 9)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(2):\n        qc.cry(-math.pi, i+10, i+9)\n      for i in range(n-13):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-13-i)), i+12, i+13)\n      for i in range(n-13):\n        qc.cry(-math.pi, i+13, i+12)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      qc.cry(2*math.acos(math.sqrt(4.0/(n-5))), 5, 9)\n      qc.cx(9, 5)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(3):\n        qc.cry(-math.pi, i+6, i+5)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-9))), 9, 12)\n      qc.cx(12, 9)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-9-i)), i+9, i+10)\n      for i in range(2):\n        qc.cry(-math.pi, i+10, i+9)\n      qc.cry(2*math.acos(math.sqrt(2.0/(n-12))), 12, 14)\n      qc.cx(14, 12)\n      for i in range(1):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-13-i)), i+12, i+13)\n      for i in range(1):\n        qc.cry(-math.pi, i+13, i+12)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8)), 8, 11)\n      qc.cx(11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8)), 8, 11)\n      qc.cx(11, 8)\n      qc.cry(2*math.acos(math.sqrt(0.5), 11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.ch(13, 14)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8)), 8, 11)\n      qc.cx(11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8)), 8, 11)\n      qc.cx(11, 8)\n      qc.ch(11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.ch(13, 14)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8)), 8, 11)\n      qc.cx(11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8)), 8, 11)\n      qc.cx(11, 8)\n      qc.ch(11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.ch(13, 14)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8)), 8, 11)\n      qc.cx(11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cx(11, 8)\n      qc.ch(11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.ch(13, 14)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 8, "result": "WA", "execution_time": "1300 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cx(11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cx(11, 8)\n      qc.ch(11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.ch(13, 14)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 9, "result": "WA", "execution_time": "1597 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cx(11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cx(11, 8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 13)\n      qc.cx(13, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 12)\n      qc.cry(-math.pi, 12, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 13, 14)\n      qc.cry(-math.pi, 14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 10, "result": "WA", "execution_time": "1605 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 0, 4)\n      qc.cry(-math.pi, 4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 0, 4)\n      qc.cry(-math.pi, 4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 0, 4)\n      qc.cry(-math.pi, 4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 13)\n      qc.cry(-math.pi, 13, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 12)\n      qc.cry(-math.pi, 12, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 13, 14)\n      qc.cry(-math.pi, 14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(, 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(, 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(, 0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 13)\n      qc.cry(-math.pi, 13, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 12)\n      qc.cry(-math.pi, 12, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 13, 14)\n      qc.cry(-math.pi, 14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 12, "result": "WA", "execution_time": "1545 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 13)\n      qc.cry(-math.pi, 13, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 12)\n      qc.cry(-math.pi, 12, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 13, 14)\n      qc.cry(-math.pi, 14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 13, "result": "WA", "execution_time": "1864 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 13)\n      qc.cry(-math.pi, 13, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 11, 12)\n      qc.cry(-math.pi, 12, 11)\n      qc.cry(2*math.acos(math.sqrt(0.5)), 13, 14)\n      qc.cry(-math.pi, 14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 14, "result": "WA", "execution_time": "1838 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cx(11, 8)\n      qc.ch(11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.cx(12, 11)\n      qc.ch(13, 14)\n      qc.cx(14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 15, "result": "WA", "execution_time": "1671 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      qc.ch(11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.cx(12, 11)\n      qc.ch(13, 14)\n      qc.cx(14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 16, "result": "WA", "execution_time": "2128 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      qc.ch(11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.cx(12, 11)\n      qc.ch(13, 14)\n      qc.cx(14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AA7955557FD95", "submission_order": 17, "result": "AC", "execution_time": "1734 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n < 6:\n      qc.ry(2*math.acos(1.0/math.sqrt(n)), 0)\n      for i in range(n-2):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-i-1)), i, i+1)\n      for i in range(n-1):\n        qc.cry(-math.pi, n-2-i, n-1-i)\n      qc.ry(-math.pi, 0)\n    elif n < 10:\n      qc.ry(2*math.acos(math.sqrt((n-5.0)/n)), 5)\n      qc.cx(5, 0)\n      qc.x(5)\n      for i in range(4):\n        qc.cry(2*math.acos(1.0/math.sqrt(5-i)), i, i+1)\n      for i in range(4):\n        qc.cry(-math.pi, i+1, i)\n      for i in range(n-6):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-5-i)), i+5, i+6)\n      for i in range(n-6):\n        qc.cry(-math.pi, i+6, i+5)\n    elif n < 12:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      for i in range(n-9):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-8-i)), i+8, i+9)\n      for i in range(n-9):\n        qc.cry(-math.pi, i+9, i+8)\n    elif n < 15:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      for i in range(n-12):\n        qc.cry(2*math.acos(1.0/math.sqrt(n-11-i)), i+11, i+12)\n      for i in range(n-12):\n        qc.cry(-math.pi, i+12, i+11)\n    else:\n      qc.ry(2*math.acos(math.sqrt((n-8.0)/n)), 8)\n      qc.cx(8, 0)\n      qc.x(8)\n      qc.ch(0, 4)\n      qc.cx(4, 0)\n      for i in range(3):\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i, i+1)\n        qc.cry(2*math.acos(1.0/math.sqrt(4-i)), i+4, i+5)\n      for i in range(3):\n        qc.cry(-math.pi, i+1, i)\n        qc.cry(-math.pi, i+5, i+4)\n      qc.cry(2*math.acos(math.sqrt(3.0/(n-8))), 8, 11)\n      qc.cry(-math.pi, 11, 8)\n      for i in range(2):\n        qc.cry(2*math.acos(1.0/math.sqrt(3-i)), i+8, i+9)\n      for i in range(2):\n        qc.cry(-math.pi, i+9, i+8)\n      qc.ch(11, 13)\n      qc.cx(13, 11)\n      qc.ch(11, 12)\n      qc.cx(12, 11)\n      qc.ch(13, 14)\n      qc.cx(14, 13)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AC3CF6A8D1CBB", "submission_order": 1, "result": "RE", "execution_time": "1381 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    count = 1\n    queue = [(n // 2, n, 0)]\n    while len(quque):\n        a, b, control = queue.pop(0)\n        if a == 0:\n            continue\n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n        count += 1\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AC3CF6A8D1CBB", "submission_order": 2, "result": "RE", "execution_time": "1609 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    count = 1\n    queue = [(n // 2, n, 0)]\n    while len(quque):\n        a, b, control = queue.pop(0)\n        if a == 0:\n            continue\n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n        count += 1\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AC3CF6A8D1CBB", "submission_order": 3, "result": "AC", "execution_time": "1831 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    count = 1\n\n    queue = [(n // 2, n, 0)]\n\n    while len(queue):\n        a, b, control = queue.pop(0)\n \n        if a == 0:\n            continue\n \n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n \n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n \n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n \n        count += 1\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "ACB622EC8767A", "submission_order": 1, "result": "AC", "execution_time": "2138 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n \n    count = 1\n \n    # queue = [(a, b, control bit of CRy), ...]\n    queue = [(n // 2, n, 0)]\n \n    # breadth first search\n    while len(queue):\n        a, b, control = queue.pop(0)\n \n        if a == 0:\n            continue\n \n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n \n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n \n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n \n        count += 1\n \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AD52F4C325A5A", "submission_order": 1, "result": "AC", "execution_time": "1738 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, acos, sqrt\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(0)\n    def f(l: int, r: int) -> None:\n        if r - l == 1:\n            return\n        mid = (l + r) // 2\n        qc.cry(2 * acos(sqrt((mid-l)/(r-l))), l, mid)\n        qc.cx(mid, l)\n        f(l, mid)\n        f(mid, r)\n    f(0, n)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AE201A7C55123", "submission_order": 1, "result": "AC", "execution_time": "1777 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import asin\n\n\ndef move(qc, f, t, ratio):\n    theta = 2 * asin(ratio**0.5)\n    qc.cry(theta, f, t)\n    qc.cx(t, f)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    parent = [None]\n    for i in range(1, n):\n        for r in (8, 4, 2, 1):\n            if i & r:\n                parent.append(i - r)\n                break\n\n    # print(parent)\n\n    ww = [0] * n\n    for i in range(n - 1, -1, -1):\n        ww[i] += 1 / n\n        if parent[i] is not None:\n            ww[parent[i]] += ww[i]\n\n    # print(ww)\n\n    xx = [0] * n\n    xx[0] = 1\n\n    for i in range(1, n):\n        p = parent[i]\n        move(qc, p, i, ww[i] / xx[p])\n        xx[p] -= ww[i]\n        xx[i] = ww[i]\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AE28B0E89E1E1", "submission_order": 1, "result": "RE", "execution_time": "1307 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef theta(n: int, m: int) -> float:\n    return 2 * math.acos(math.sqrt(m/n))\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    a = 1\n    while a*2 < n:\n        a *= 2\n    \n    qc.x(0)\n    while a > 0:\n        j = 0\n        while j + a <= n:\n            print(j, j+a)\n            qc.cry(theta(min(2*a,n), a), j, j+a)\n            qc.cx(j+a,j)\n            j += a+1\n        a //= 2\n \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AE28B0E89E1E1", "submission_order": 2, "result": "RE", "execution_time": "1599 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n\n    def theta(n: int, m: int) -> float:\n        return 2 * math.acos(math.sqrt(m/n))\n\n    a = 1\n    while a*2 < n:\n        a *= 2\n    \n    qc.x(0)\n    while a > 0:\n        j = 0\n        while j + a <= n:\n            print(j, j+a)\n            qc.cry(theta(min(2*a,n), a), j, j+a)\n            qc.cx(j+a,j)\n            j += a+1\n        a //= 2\n \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AE28B0E89E1E1", "submission_order": 3, "result": "WA", "execution_time": "1286 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n\n    def theta(n: int, m: int) -> float:\n        return 2 * math.acos(math.sqrt(m/n))\n\n    a = 1\n    while a*2 < n:\n        a *= 2\n    \n    qc.x(0)\n    while a > 0:\n        j = 0\n        while j + a < n:\n            # print(j, j+a)\n            qc.cry(theta(min(2*a, n), a), j, j+a)\n            qc.cx(j+a,j)\n            j += a+1\n        a //= 2\n \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AE28B0E89E1E1", "submission_order": 4, "result": "AC", "execution_time": "1705 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef theta(n: int, m: int) -> float:\n    return 2 * math.acos(math.sqrt(m/n))\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    a = 1\n    while a*2 < n:\n        a *= 2\n    \n    qc.x(0)\n    while a > 0:\n        j = 0\n        while j + a < n:\n            qc.cry(theta(min(2*a, n-j), a), j, j+a)\n            qc.cx(j+a, j)\n            j += 2*a\n        a //= 2\n \n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AE345EC443A0F", "submission_order": 1, "result": "AC", "execution_time": "1895 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    split(qc, 0, n)\n\n    return qc\n\ndef split(qc, stIncl, edExcl):\n    if stIncl + 1 == edExcl:\n        return\n\n    mid = (stIncl + edExcl) // 2\n    left = mid - stIncl\n    right = edExcl - mid\n    print(f'{left=} {right=}')\n\n    angle = 2*math.atan(math.sqrt(right/left))\n    qc.cry(angle, stIncl, mid)\n    qc.cx(mid, stIncl)\n\n    split(qc, stIncl, mid)\n    split(qc, mid, edExcl)\n\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AF500A187CD5A", "submission_order": 1, "result": "AC", "execution_time": "1870 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i,j in [(0,8),(0,4),(8,12),(0,2),(4,6),(8,10),(12,14),(0,1),(2,3),(4,5),(6,7),(8,9),(10,11),(12,13)]:\n        if j >= n:\n            continue\n        theta = math.atan(math.sqrt(min(j-i,n-j)/(j-i)))*2\n        qc.cry(theta, i, j)\n        qc.cx(j,i)\n    return qc\n'''"}
{"problem": "QPC003_A6", "user": "AFAEA9300DEC6", "submission_order": 1, "result": "UGE", "execution_time": "1379 ms", "memory": "154 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(l: int, k: int) -> float:\n    return math.asin(math.sqrt(l/k)) * 2\n\n\ndef solve_inner(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    if n == 1:\n        return qc\n    else:\n        half = n // 2\n        qc_l = solve_inner(half)\n        qc_r = solve_inner(n - half)\n        qc.cry(theta(n-half, n), 0, half)\n        qc.cx(half, 0)\n        qc.append(qc_l, range(half))\n        qc.append(qc_r, range(half, n))\n        return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    qc.append(solve_inner(n), range(n))\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve_inner(3)\n    print(qc)\n'''"}
{"problem": "QPC003_A6", "user": "AFAEA9300DEC6", "submission_order": 2, "result": "AC", "execution_time": "1931 ms", "memory": "158 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef theta(l: int, k: int) -> float:\n    return math.asin(math.sqrt(l/k)) * 2\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    def solve_inner(k: int, l: int, qc_l: QuantumCircuit) -> QuantumCircuit:\n        if k == 1:\n            return qc_l\n        else:\n            half = k // 2\n            qc_l.cry(theta(k-half, k), l, l + half)\n            qc_l.cx(l + half, l)\n            qc_l = solve_inner(half, l, qc_l)\n            qc_l = solve_inner(k - half, l + half, qc_l)\n            return qc_l\n    qc = solve_inner(n, 0, qc)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_B1", "user": "A07BB9D724C52", "submission_order": 1, "result": "AC", "execution_time": "1409 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A085687CE583B", "submission_order": 1, "result": "RE", "execution_time": "1559 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A085687CE583B", "submission_order": 2, "result": "AC", "execution_time": "1588 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A09DA4793FCDE", "submission_order": 1, "result": "AC", "execution_time": "1412 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A0CA361036427", "submission_order": 1, "result": "AC", "execution_time": "1236 ms", "memory": "155 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A0CCD63326EF3", "submission_order": 1, "result": "WA", "execution_time": "1569 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A0CCD63326EF3", "submission_order": 2, "result": "AC", "execution_time": "1498 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A0CFA971975DF", "submission_order": 1, "result": "AC", "execution_time": "1683 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A1017BC0CD196", "submission_order": 1, "result": "AC", "execution_time": "1576 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)  \n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A10F87143A09A", "submission_order": 1, "result": "AC", "execution_time": "1376 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A153051CCFE83", "submission_order": 1, "result": "AC", "execution_time": "1639 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A171D50FBA79E", "submission_order": 1, "result": "AC", "execution_time": "1653 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_B1", "user": "A1BF89254EDA9", "submission_order": 1, "result": "AC", "execution_time": "1642 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A1CDA20FCAD97", "submission_order": 1, "result": "RE", "execution_time": "1215 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, acos, sqrt\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A1CDA20FCAD97", "submission_order": 2, "result": "RE", "execution_time": "1599 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, acos, sqrt\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A1CDA20FCAD97", "submission_order": 3, "result": "AC", "execution_time": "1370 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A1DB4E247AE36", "submission_order": 1, "result": "AC", "execution_time": "1493 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A1EE323474711", "submission_order": 1, "result": "AC", "execution_time": "1573 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A1F138E2EC9E9", "submission_order": 1, "result": "AC", "execution_time": "1552 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A292DFFE7CED7", "submission_order": 1, "result": "AC", "execution_time": "1527 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A2B0590076D37", "submission_order": 1, "result": "AC", "execution_time": "1897 ms", "memory": "154 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\nif __name__ == \"__main__\":\n    qc = solve()\n    print(qc)\n'''"}
{"problem": "QPC003_B1", "user": "A2DDDE40001D0", "submission_order": 1, "result": "AC", "execution_time": "1771 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_B1", "user": "A2EBF549C10C6", "submission_order": 1, "result": "AC", "execution_time": "1836 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A2F0D226654F8", "submission_order": 1, "result": "AC", "execution_time": "1435 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A2FD3A68777D1", "submission_order": 1, "result": "AC", "execution_time": "1528 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A2FF997417378", "submission_order": 1, "result": "AC", "execution_time": "1521 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A33BB6BB2D303", "submission_order": 1, "result": "AC", "execution_time": "1560 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A33F09B066F34", "submission_order": 1, "result": "WA", "execution_time": "1625 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A33F09B066F34", "submission_order": 2, "result": "AC", "execution_time": "1429 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A3ACE48C2F234", "submission_order": 1, "result": "AC", "execution_time": "1419 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A3AD172A4576B", "submission_order": 1, "result": "AC", "execution_time": "1549 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n \n    return qc\n\nqc = solve()\n'''"}
{"problem": "QPC003_B1", "user": "A3B73B77B025F", "submission_order": 1, "result": "AC", "execution_time": "1552 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A3EE923CBF501", "submission_order": 1, "result": "AC", "execution_time": "2038 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A409895568302", "submission_order": 1, "result": "AC", "execution_time": "1533 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A488EE295E1F8", "submission_order": 1, "result": "AC", "execution_time": "1581 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A490D3990506F", "submission_order": 1, "result": "AC", "execution_time": "1592 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A4F6F4DC88F2E", "submission_order": 1, "result": "AC", "execution_time": "1532 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A4FEDA52C67C7", "submission_order": 1, "result": "AC", "execution_time": "1381 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A51F36122B40E", "submission_order": 1, "result": "AC", "execution_time": "1471 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A52DE84E7C2B5", "submission_order": 1, "result": "AC", "execution_time": "1494 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A54E12B3A262B", "submission_order": 1, "result": "AC", "execution_time": "1434 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A586390632E17", "submission_order": 1, "result": "AC", "execution_time": "1462 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A59B3A62C6B9D", "submission_order": 1, "result": "AC", "execution_time": "1389 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A5B3697CA529F", "submission_order": 1, "result": "AC", "execution_time": "1556 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A5D25A00868B9", "submission_order": 1, "result": "AC", "execution_time": "1196 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A635352B46C47", "submission_order": 1, "result": "AC", "execution_time": "1590 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 1, "result": "WA", "execution_time": "1566 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.extensions import UnitaryGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    A = np.array([[0, 1], [1, 0]])  # 例としてパウリXゲートを使用\n\n    # カスタムゲートを作成\n    custom_gate = UnitaryGate(A, label='A')\n    qc.append(custom_gate, [0])\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.extensions import UnitaryGate\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    A = np.array([[0, 1], [1, 0]])  # 例としてパウリXゲートを使用\n\n    # カスタムゲートを作成\n    custom_gate = UnitaryGate(A, label='A')\n    qc.append(custom_gate, [0])\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    matrix = [[[0, 1], [1, 0]]]\n    gate = UnitaryGate(matrix)\n    \n    circuit = QuantumCircuit(2)\n    circuit.append(gate, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    matrix = [[[0, 1], [1, 0]]]\n    gate = UnitaryGate(matrix)\n    \n    circuit = QuantumCircuit(1)\n    circuit.append(gate, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info.operators.operator import Operator\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    # ユニタリー行列を用意(今回は適当に単位行列)\n    unitary = np.array([[0, 1], [1, 0]])\n\n    # ユニタリー行列からオペレーターを作成\n    operator = Operator(unitary)\n\n    # 量子回路(qubit0番と1番)にオペレーターを作用(ユニタリーでなかった場合はエラーが出る)\n    qc.append(operator, [0])\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 7, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info.operators.operator import Operator\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    # ユニタリー行列を用意(今回は適当に単位行列)\n    unitary = [[0, 1], [1, 0]]\n\n    # ユニタリー行列からオペレーターを作成\n    operator = Operator(unitary)\n\n    # 量子回路(qubit0番と1番)にオペレーターを作用(ユニタリーでなかった場合はエラーが出る)\n    qc.append(operator, [0])\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 8, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info.operators.operator import Operator\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    # ユニタリー行列を用意(今回は適当に単位行列)\n    unitary = [[0, 1], [1, 0]]\n\n    # ユニタリー行列からオペレーターを作成\n    operator = Operator(unitary)\n\n    # 量子回路(qubit0番と1番)にオペレーターを作用(ユニタリーでなかった場合はエラーが出る)\n    qc.append(operator, [0])\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A666FBF7116E7", "submission_order": 9, "result": "AC", "execution_time": "1515 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A676FD60A73F9", "submission_order": 1, "result": "AC", "execution_time": "1311 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A75431C053D1A", "submission_order": 1, "result": "AC", "execution_time": "1593 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A7929480D2608", "submission_order": 1, "result": "AC", "execution_time": "1499 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, HGate, CXGate, MCPhaseGate \nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A7A24B94BF17F", "submission_order": 1, "result": "AC", "execution_time": "1586 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A83649639C99C", "submission_order": 1, "result": "AC", "execution_time": "1499 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A883466AF4756", "submission_order": 1, "result": "AC", "execution_time": "1849 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A8E390E5E1D2D", "submission_order": 1, "result": "AC", "execution_time": "1466 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A9772B8612E7E", "submission_order": 1, "result": "RE", "execution_time": "1757 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.cx(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A9772B8612E7E", "submission_order": 2, "result": "AC", "execution_time": "1801 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A978D71994E51", "submission_order": 1, "result": "RE", "execution_time": "1613 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.swap(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A978D71994E51", "submission_order": 2, "result": "AC", "execution_time": "1717 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A98D96BE05496", "submission_order": 1, "result": "AC", "execution_time": "1583 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A9A00A6F5F156", "submission_order": 1, "result": "AC", "execution_time": "1571 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A9AB811FDCC49", "submission_order": 1, "result": "AC", "execution_time": "1217 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "A9BD19F147F5A", "submission_order": 1, "result": "AC", "execution_time": "1403 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AA008D11B342F", "submission_order": 1, "result": "WA", "execution_time": "1578 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AA008D11B342F", "submission_order": 2, "result": "AC", "execution_time": "1217 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AA20659AC9692", "submission_order": 1, "result": "AC", "execution_time": "1229 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AA44E32CF1616", "submission_order": 1, "result": "AC", "execution_time": "1637 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AA608CCD7E165", "submission_order": 1, "result": "AC", "execution_time": "1488 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AA6D5C240B03E", "submission_order": 1, "result": "AC", "execution_time": "1213 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AA6E5419908D3", "submission_order": 1, "result": "AC", "execution_time": "1611 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AA6F0C313C4D4", "submission_order": 1, "result": "AC", "execution_time": "1202 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AABCD8F672A7D", "submission_order": 1, "result": "AC", "execution_time": "1546 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AAC197289B885", "submission_order": 1, "result": "AC", "execution_time": "1714 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    # Aplicamos la compuerta X\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AB2497C4697C6", "submission_order": 1, "result": "AC", "execution_time": "1556 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AB5D1D1F57DAD", "submission_order": 1, "result": "AC", "execution_time": "1793 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ABA9D6DFE378F", "submission_order": 1, "result": "AC", "execution_time": "2092 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Pauli-X gate to the qubit\n    qc.x(0)  # This applies the NOT operation on the qubit at index 0\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ABAEA133937F4", "submission_order": 1, "result": "AC", "execution_time": "1616 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ABB1C5B1C7D31", "submission_order": 1, "result": "AC", "execution_time": "1883 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ABDBA58F1A1CB", "submission_order": 1, "result": "AC", "execution_time": "1749 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ABED0B536E234", "submission_order": 1, "result": "AC", "execution_time": "1389 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ABF9D34388C88", "submission_order": 1, "result": "AC", "execution_time": "1535 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AC7522593CA37", "submission_order": 1, "result": "AC", "execution_time": "1621 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ACA586489F89F", "submission_order": 1, "result": "AC", "execution_time": "1229 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ACBA1AA217C7C", "submission_order": 1, "result": "AC", "execution_time": "1467 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ACC8664CA1472", "submission_order": 1, "result": "AC", "execution_time": "1498 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ACD1049F45557", "submission_order": 1, "result": "AC", "execution_time": "1602 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AD7582EC54C3A", "submission_order": 1, "result": "AC", "execution_time": "1976 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "ADA045425A93D", "submission_order": 1, "result": "AC", "execution_time": "1648 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(*args) -> QuantumCircuit:\n\tqc = QuantumCircuit(1)\n\tqc.x(0)\n\treturn qc\n'''"}
{"problem": "QPC003_B1", "user": "AE133B42AFF82", "submission_order": 1, "result": "AC", "execution_time": "1661 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AE23E6A66233C", "submission_order": 1, "result": "AC", "execution_time": "1310 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AE4637F37E40A", "submission_order": 1, "result": "WA", "execution_time": "1599 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AE4637F37E40A", "submission_order": 2, "result": "AC", "execution_time": "1720 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AE50355CF90E4", "submission_order": 1, "result": "AC", "execution_time": "1948 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AE5F3F63BB27F", "submission_order": 1, "result": "AC", "execution_time": "1486 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AE7F17A6FDC5F", "submission_order": 1, "result": "AC", "execution_time": "1530 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AEA81E2DABF60", "submission_order": 1, "result": "AC", "execution_time": "1468 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AEE45C36BD79A", "submission_order": 1, "result": "AC", "execution_time": "1224 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AEF3917179E83", "submission_order": 1, "result": "AC", "execution_time": "1414 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AF1D674E66F86", "submission_order": 1, "result": "AC", "execution_time": "1519 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AF2FAA33ACCE6", "submission_order": 1, "result": "AC", "execution_time": "1630 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AF5882259C7AC", "submission_order": 1, "result": "RE", "execution_time": "1466 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AF5882259C7AC", "submission_order": 2, "result": "RE", "execution_time": "1710 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AF5882259C7AC", "submission_order": 3, "result": "AC", "execution_time": "1291 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AF717A2A4959D", "submission_order": 1, "result": "AC", "execution_time": "1841 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B1", "user": "AFD03DF6267A1", "submission_order": 1, "result": "AC", "execution_time": "1818 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A01B941D6CE96", "submission_order": 1, "result": "RE", "execution_time": "1357 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.append(o)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A01B941D6CE96", "submission_order": 2, "result": "WA", "execution_time": "1258 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    \n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A01B941D6CE96", "submission_order": 3, "result": "AC", "execution_time": "1601 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    \n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n    qc.z(y[0])\n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A03F7D545302C", "submission_order": 1, "result": "WA", "execution_time": "1244 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(x[0], y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A03F7D545302C", "submission_order": 2, "result": "WA", "execution_time": "1245 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.z(x[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A03F7D545302C", "submission_order": 3, "result": "RE", "execution_time": "1479 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cz(o[0], y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A03F7D545302C", "submission_order": 4, "result": "WA", "execution_time": "1404 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.cz(x[0], y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A03F7D545302C", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n    qc.h(x)\n        qc.cz(x[i], y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A03F7D545302C", "submission_order": 6, "result": "WA", "execution_time": "1183 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cz(x[i], y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A03F7D545302C", "submission_order": 7, "result": "WA", "execution_time": "1273 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.z(x[i])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A057851793EAC", "submission_order": 1, "result": "WA", "execution_time": "1227 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace= True)\n    qc.z(y[0])\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A057851793EAC", "submission_order": 2, "result": "WA", "execution_time": "1352 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    \n    qc.compose(o, inplace= True)\n    qc.z(y[0])\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A057851793EAC", "submission_order": 3, "result": "RE", "execution_time": "1336 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    qc.compose(o, inplace= True)\n    qc.z(y[0])\n    qc.compose(o.inverse, inplace = True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A057851793EAC", "submission_order": 4, "result": "AC", "execution_time": "1833 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    qc.compose(o, inplace= True)\n    qc.z(y[0])\n    qc.compose(o, inplace= True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A0765C8249D2D", "submission_order": 1, "result": "RE", "execution_time": "1354 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tqc.compose(o, inplace = True)\n\tfor i in range(n):\n\t\tqc.append(GlobalPhaseGate(pi / n).control(y[0]), x[i])\n\treturn qc\n'''"}
{"problem": "QPC003_B2", "user": "A0765C8249D2D", "submission_order": 2, "result": "RE", "execution_time": "1302 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tqc.compose(o, inplace = True)\n\tfor i in range(n):\n\t\tqc.append(PhaseGate(pi / n).control(y[0]), x[i])\n\treturn qc\n'''"}
{"problem": "QPC003_B2", "user": "A0765C8249D2D", "submission_order": 3, "result": "RE", "execution_time": "1245 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tqc.compose(o, inplace = True)\n\tfor i in range(n):\n\t\tqc.append(PhaseGate(pi / n).control(), [y[0], x[i]])\n\treturn qc\n'''"}
{"problem": "QPC003_B2", "user": "A0765C8249D2D", "submission_order": 4, "result": "RE", "execution_time": "1224 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tqc.compose(o, qubits = x, inplace = True)\n\tfor i in range(n):\n\t\tqc.append(PhaseGate(pi / n).control(), [y[0], x[i]])\n\treturn qc\n'''"}
{"problem": "QPC003_B2", "user": "A0765C8249D2D", "submission_order": 5, "result": "WA", "execution_time": "1279 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tqc.compose(o, inplace = True)\n\tfor i in range(n):\n\t\tqc.append(PhaseGate(pi / n).control(), [y[0], x[i]])\n\treturn qc\n'''"}
{"problem": "QPC003_B2", "user": "A0765C8249D2D", "submission_order": 6, "result": "WA", "execution_time": "1222 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tqc.compose(o, inplace = True)\n\tfor i in range(n):\n\t\tqc.append(PhaseGate(pi).control(), [y[0], x[i]])\n\treturn qc\n'''"}
{"problem": "QPC003_B2", "user": "A0765C8249D2D", "submission_order": 7, "result": "AC", "execution_time": "1876 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import MCXGate, PhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n\tx, y = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(x, y)\n\tqc.compose(o, inplace = True)\n\tqc.z(y)\n\tqc.compose(o, inplace = True)\n\treturn qc\n'''"}
{"problem": "QPC003_B2", "user": "A08F8FC9490FD", "submission_order": 1, "result": "AC", "execution_time": "2108 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A09530FABEA4E", "submission_order": 1, "result": "WA", "execution_time": "1463 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    qc.append(o, range(n+1))\n    qc.cz(x[0], y)\n    qc.h(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A09530FABEA4E", "submission_order": 2, "result": "AC", "execution_time": "1608 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A11970A5AD721", "submission_order": 1, "result": "WA", "execution_time": "1480 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(x)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.h(x)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A11970A5AD721", "submission_order": 2, "result": "WA", "execution_time": "1245 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(x)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.h(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A11970A5AD721", "submission_order": 3, "result": "WA", "execution_time": "1200 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(x)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A11970A5AD721", "submission_order": 4, "result": "RE", "execution_time": "1234 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(x)\n    qc.h(y)\n    qc.compose(x, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A1D8FC642775E", "submission_order": 1, "result": "WA", "execution_time": "1239 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(1, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    qc.x(y)\n    qc.h(y)\n    \n    qc.compose(o, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A1D8FC642775E", "submission_order": 2, "result": "WA", "execution_time": "1262 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(1, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    qc.x(y)\n    qc.h(y)\n    \n    qc.compose(o, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A1D941B54891C", "submission_order": 1, "result": "WA", "execution_time": "1344 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cz(x[i], y[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A2D5D2F36D1B6", "submission_order": 1, "result": "AC", "execution_time": "1727 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A312239C55078", "submission_order": 1, "result": "WA", "execution_time": "1514 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n\n    qc.z(0)\n\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A312239C55078", "submission_order": 2, "result": "WA", "execution_time": "1662 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n\n    qc.z(0)\n\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A312239C55078", "submission_order": 3, "result": "AC", "execution_time": "1789 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n\n    qc.z(y)\n\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A32FA74DEB747", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n\n    qc.compose(o.inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A32FA74DEB747", "submission_order": 2, "result": "WA", "execution_time": "1226 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.z(y[0])\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A32FA74DEB747", "submission_order": 3, "result": "WA", "execution_time": "1289 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for c in range(2 ** n):\n        # compute\n        for i in range(n):\n            if (1 << i) & c:\n                qc.x(i)\n        # oracle\n        qc.compose(o, inplace=True)\n        # un-compute\n        for i in range(n):\n            if (1 << i) & c:\n                qc.x(i)\n        # barrier\n        qc.barrier()\n\n    qc = qc.reverse_bits()\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A32FA74DEB747", "submission_order": 4, "result": "WA", "execution_time": "1364 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for c in range(2 ** n):\n        # compute\n        for i in range(n):\n            if (1 << i) & c:\n                qc.x(i)\n        # oracle\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        # un-compute\n        for i in range(n):\n            if (1 << i) & c:\n                qc.x(i)\n        # barrier\n        qc.barrier()\n\n    qc = qc.reverse_bits()\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A32FA74DEB747", "submission_order": 5, "result": "WA", "execution_time": "1308 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for c in range(2 ** n):\n        # compute\n        for i in range(n):\n            if (1 << i) & c:\n                qc.x(i)\n        # oracle\n        qc.compose(o, inplace=True)\n        qc.cz(y, x[0])\n        # un-compute\n        for i in range(n):\n            if (1 << i) & c:\n                qc.x(i)\n        # barrier\n        qc.barrier()\n\n    qc = qc.reverse_bits()\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A32FA74DEB747", "submission_order": 6, "result": "WA", "execution_time": "1606 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.cz(y, x[0])\n\n    qc = qc.reverse_bits()\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A32FA74DEB747", "submission_order": 7, "result": "WA", "execution_time": "1483 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.cz(y, x[0])\n\n    qc = qc.reverse_bits()\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A45986C9F699B", "submission_order": 1, "result": "WA", "execution_time": "1217 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cry(2*pi, n, i)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A45986C9F699B", "submission_order": 2, "result": "WA", "execution_time": "1195 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cz(n, i)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A45986C9F699B", "submission_order": 3, "result": "WA", "execution_time": "1599 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(1, n+1):\n        qc.x(i)\n        qc.cz(0, i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A45986C9F699B", "submission_order": 4, "result": "WA", "execution_time": "1299 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.z(0)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(1, n+1):\n        qc.x(i)\n        qc.cz(0, i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A45986C9F699B", "submission_order": 5, "result": "WA", "execution_time": "1411 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.z(n)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(0, n):\n        qc.x(i)\n        qc.cz(n, i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A45986C9F699B", "submission_order": 6, "result": "WA", "execution_time": "1536 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.ry(2*pi, n)\n    for i in range(n):\n        qc.cry(2*pi, n, i)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A4B6062B1E47A", "submission_order": 1, "result": "AC", "execution_time": "1670 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A4CD8471FC76A", "submission_order": 1, "result": "AC", "execution_time": "1916 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A4D6990569136", "submission_order": 1, "result": "AC", "execution_time": "1751 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A4F2A1527C5F4", "submission_order": 1, "result": "RE", "execution_time": "1333 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n, 'x'), QuantumRegister(1, 'y')\n    qc = QuantumCircuit(x, y)\n    qc.compose(o, inplace=True)\n    qc.z(y[0]).c_if(y, 1)\n    qc.compose(o.inverse(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A52C325324F21", "submission_order": 1, "result": "WA", "execution_time": "1487 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.compose(o, inplace=True)\n    qc.cz(x[0], y[0])\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A52C325324F21", "submission_order": 2, "result": "AC", "execution_time": "1944 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A57C63B033C34", "submission_order": 1, "result": "RE", "execution_time": "1166 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o, inplace=True)\n    qc.z(n)\n    qc = qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A57C63B033C34", "submission_order": 2, "result": "AC", "execution_time": "1633 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A59E2AF9CD747", "submission_order": 1, "result": "AC", "execution_time": "1974 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o.inverse(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A5D1E2291700F", "submission_order": 1, "result": "WA", "execution_time": "1815 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(1, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Apply Hadamard gates to create superposition\n    qc.h(x)\n    \n    # Step 2: Apply the oracle\n    qc.compose(o, inplace=True)\n    \n    # Step 3: Apply Hadamard gates again to the x register\n    qc.h(x)\n    \n    # Step 4: Apply a controlled-Z gate to flip the phase\n    qc.cz(x, y)\n    \n    # Step 5: Apply Hadamard gates one more time to the x register\n    qc.h(x)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A5D1E2291700F", "submission_order": 2, "result": "WA", "execution_time": "1886 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(1, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Apply Hadamard gates to create superposition\n    qc.h(x)\n    \n    # Step 2: Apply the oracle\n    qc.compose(o, inplace=True)\n    \n    # Step 3: Apply Hadamard gates to the ancillary qubit\n    qc.h(y)\n    \n    # Step 4: Apply a controlled-Z gate to flip the phase\n    qc.cz(x, y)\n    \n    # Step 5: Apply Hadamard gates to the ancillary qubit again\n    qc.h(y)\n    \n    # Step 6: Apply Hadamard gates to the x register again\n    qc.h(x)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A5D1E2291700F", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y[0])\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A66F46C0C6F11", "submission_order": 1, "result": "RE", "execution_time": "1207 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o,implace=True)\n    qc.z(n)\n    qc.x(n)\n    qc.compose(o,implace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A66F46C0C6F11", "submission_order": 2, "result": "RE", "execution_time": "1301 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o,implace=True)\n    qc.z(y)\n    \n    qc.compose(o,implace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A66F46C0C6F11", "submission_order": 3, "result": "RE", "execution_time": "1174 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o,implace=True)\n    qc.z(y)\n    qc.compose(o,implace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A66F46C0C6F11", "submission_order": 4, "result": "AC", "execution_time": "1656 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A75A2B01C2DD2", "submission_order": 1, "result": "WA", "execution_time": "1168 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.cp(math.pi, y, x[0])\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A75A2B01C2DD2", "submission_order": 2, "result": "AC", "execution_time": "1717 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8016DF6880B5", "submission_order": 1, "result": "WA", "execution_time": "1498 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(n,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8016DF6880B5", "submission_order": 2, "result": "WA", "execution_time": "1432 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.cz(n,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8016DF6880B5", "submission_order": 3, "result": "WA", "execution_time": "1447 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cz(n,i)\n        \n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8016DF6880B5", "submission_order": 4, "result": "WA", "execution_time": "1234 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cz(n,i)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8016DF6880B5", "submission_order": 5, "result": "WA", "execution_time": "1446 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cz(n,i)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8E24B2C01C56", "submission_order": 1, "result": "WA", "execution_time": "1211 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(n)\n    qc.x(n)\n    qc.compose(o, inplace=True)\n    qc.x(n)\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8E24B2C01C56", "submission_order": 2, "result": "RE", "execution_time": "1120 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    y.h(0)\n    y.x(0)\n    qc.compose(o, inplace=True)\n    y.x(0)\n    y.h(0)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8E24B2C01C56", "submission_order": 3, "result": "AC", "execution_time": "1739 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(n)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8E9AF561B46A", "submission_order": 1, "result": "WA", "execution_time": "1322 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.x(n)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A8E9AF561B46A", "submission_order": 2, "result": "AC", "execution_time": "1595 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A911F67BD1934", "submission_order": 1, "result": "WA", "execution_time": "1414 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cz(y[0],x[0])\n    qc.x(x[0])\n    qc.cz(y[0],x[0])\n    qc.x(x[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A911F67BD1934", "submission_order": 2, "result": "AC", "execution_time": "1870 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cz(y[0],x[0])\n    qc.x(x[0])\n    qc.cz(y[0],x[0])\n    qc.x(x[0])\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A91D64858E5A3", "submission_order": 1, "result": "AC", "execution_time": "1785 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A91DC80E90BA1", "submission_order": 1, "result": "WA", "execution_time": "1584 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A91DC80E90BA1", "submission_order": 2, "result": "WA", "execution_time": "1420 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    qc.h(y)\n    qc.x(y)\n    qc.h(y)\n\n    qc.compose(o, inplace=True)\n\n    qc.h(y)\n    qc.x(y)\n    qc.h(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 1, "result": "RE", "execution_time": "1203 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.mcz(list(range(n - 1)), n)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 2, "result": "RE", "execution_time": "1217 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.mcz(list(range(n - 1)), n - 1)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 3, "result": "RE", "execution_time": "1190 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.mcz(list(range(n - 1)), n - 1)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 4, "result": "WA", "execution_time": "1462 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    mcz = ZGate().control(n)\n    qc.append(mcz, range(n + 1))\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 5, "result": "WA", "execution_time": "1281 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    mcz = ZGate().control(n)\n    qc.append(mcz, range(n + 1))\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 6, "result": "RE", "execution_time": "1499 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    mcz = ZGate().control(n)\n    qc.append(mcz, range(n + 1))\n    qc.compose(o, inplace=True)\n    assert n > 1\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 7, "result": "RE", "execution_time": "1341 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    mcz = ZGate().control(list(range(n)))\n    qc.append(mcz, range(n + 1))\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 8, "result": "RE", "execution_time": "1191 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # qc.compose(o, inplace=True)\n    mcz = ZGate().control(list(range(n)))\n    qc.append(mcz, range(n + 1))\n    # qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 9, "result": "WA", "execution_time": "1938 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    # qc.compose(o, inplace=True)\n    mcz = ZGate().control(n)\n    qc.append(mcz, range(n + 1))\n    # qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 10, "result": "WA", "execution_time": "1367 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    mcz = ZGate().control(n)\n    qc.append(mcz, range(n + 1))\n    qc.compose(o.inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 11, "result": "WA", "execution_time": "1288 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    mcz = ZGate().control(n)\n    qc.append(mcz, range(n + 1))\n    qc.mcx(list(range(n)), n)\n    qc.compose(o.inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 12, "result": "WA", "execution_time": "1418 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    mcz = ZGate().control(n)\n    qc.append(mcz, range(n + 1))\n    qc.mcx(list(range(n)), n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 13, "result": "RE", "execution_time": "1307 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cz(n)\n    qc.mcx(list(range(n)), n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 14, "result": "RE", "execution_time": "1210 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cz(n)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A935DE589F524", "submission_order": 15, "result": "AC", "execution_time": "1664 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A94B9BA05F9D7", "submission_order": 1, "result": "RE", "execution_time": "1298 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h()\n\n    for i in range(1,n):\n        qc.cz(1,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A94B9BA05F9D7", "submission_order": 2, "result": "RE", "execution_time": "1835 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h()\n\n    for i in range(o,n):\n        qc.cz(1,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A956CC16C0DD1", "submission_order": 1, "result": "AC", "execution_time": "1765 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y[0])\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 1, "result": "WA", "execution_time": "1195 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.cx(y, x[0])\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 2, "result": "WA", "execution_time": "1270 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.cx(y, x[0])\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 3, "result": "RE", "execution_time": "1202 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.mcp(math.pi, y, x)\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 4, "result": "WA", "execution_time": "1245 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.mcp(math.pi, y, x)\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport mat\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.append(MCPhaseGate(math.pi, n), n+1)\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 6, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport mat\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.mcp(-1*math.pi, y, x)\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 7, "result": "WA", "execution_time": "1491 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.mcp(-1*math.pi, y, x)\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 8, "result": "WA", "execution_time": "1566 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.append(MCPhaseGate(-1*math.pi, n), range(n+1))\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 9, "result": "WA", "execution_time": "1425 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.append(MCPhaseGate(-1*math.pi, n), range(n+1))\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 10, "result": "WA", "execution_time": "1578 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    for q in range(n):\n        qc.cz(y, q)\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 11, "result": "WA", "execution_time": "1300 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 12, "result": "WA", "execution_time": "1239 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o)\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 13, "result": "RE", "execution_time": "1341 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc = qc.compose(o, inplace=True)\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 14, "result": "WA", "execution_time": "1213 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    qc.cz(y, x[0])\n    qc.cx(y, x[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 15, "result": "WA", "execution_time": "1263 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cz(y, x[-1])\n    qc.cx(y, x[-1])\n    qc.cz(y, x[-1])\n    qc.cx(y, x[-1])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 16, "result": "RE", "execution_time": "1777 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.ch(y, x[-1])\n    qc.mcx(list(range(n-1)), n-1)\n    qc.ch(y, x[-1])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 17, "result": "RE", "execution_time": "1587 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.ch(y, x[-1])\n    qc.mcx(list(range(n-1)), n-1)\n    qc.ch(y, x[-1])\n    qc.reset(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 18, "result": "RE", "execution_time": "1262 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.ch(n, n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.ch(n, n-1)\n    qc.reset(n)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 19, "result": "RE", "execution_time": "1544 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.ch(n, n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.ch(n, n-1)\n    qc.reset(n)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 20, "result": "WA", "execution_time": "1453 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.x(x[0])\n    qc.h(x[0])\n    qc.cx(y, x[0])\n    qc.h(x[0])\n    qc.x(x[0])\n    qc.reset(n)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A971F60963270", "submission_order": 21, "result": "AC", "execution_time": "1745 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A9AA8373E31F0", "submission_order": 1, "result": "WA", "execution_time": "1174 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cz(y, 0)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A9AA8373E31F0", "submission_order": 2, "result": "AC", "execution_time": "2039 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "A9E68AFE51A79", "submission_order": 1, "result": "AC", "execution_time": "1831 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AA1712B84EC4F", "submission_order": 1, "result": "RE", "execution_time": "1225 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cry(np.pi*2, n+1, 0)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AA1712B84EC4F", "submission_order": 2, "result": "RE", "execution_time": "1206 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cry(np.pi*2, n+1, 0)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AA1712B84EC4F", "submission_order": 3, "result": "AC", "execution_time": "1715 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cry(np.pi*2, n, 0)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AA796DC568828", "submission_order": 1, "result": "AC", "execution_time": "1672 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AA9C78F91E545", "submission_order": 1, "result": "AC", "execution_time": "1863 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    # Paso 1: Aplicar el oráculo O\n    qc.compose(o, qubits=x[:] + y[:], inplace=True)\n    \n    # Paso 2: Aplicar la puerta Z al qubit auxiliar y[0]\n    qc.z(y[0])\n    \n    # Paso 3: Aplicar nuevamente el oráculo O\n    qc.compose(o, qubits=x[:] + y[:], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AABC03769A0ED", "submission_order": 1, "result": "RE", "execution_time": "1262 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    qc.z(n+1)\n    qc.compose(o, inplace=True)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AABC03769A0ED", "submission_order": 2, "result": "WA", "execution_time": "1324 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AABC03769A0ED", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.z(n+)\n    qc.compose(o, inplace=True)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AABC03769A0ED", "submission_order": 4, "result": "AC", "execution_time": "1697 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AACF15238A038", "submission_order": 1, "result": "WA", "execution_time": "1333 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.compose(o, inplace=True)\n    qc.z(y[0])\n    qc.x(y[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AACF15238A038", "submission_order": 2, "result": "RE", "execution_time": "1606 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.compose(o, inplace=True)\n    qc.cz(y[0])\n    qc.cx(y[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AACF15238A038", "submission_order": 3, "result": "RE", "execution_time": "1300 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.compose(o, inplace=True)\n    qc.cz(y[0], x[0])\n    qc.cx(y[0], y[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AACF15238A038", "submission_order": 4, "result": "AC", "execution_time": "1690 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.compose(o, inplace=True)\n    qc.z(y[0])\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AB0836EFF2CF3", "submission_order": 1, "result": "WA", "execution_time": "1473 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:」\n\n    qc.compose(o, qubits=x[:] + [y[0]], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AB0836EFF2CF3", "submission_order": 2, "result": "WA", "execution_time": "1254 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    #私はqc.compose(o, inplace=True)を今初めて知りました。mergeぐらいしか知らねぇ\n\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AB0836EFF2CF3", "submission_order": 3, "result": "AC", "execution_time": "1645 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n\n    qc.z(y[0])\n\n    qc.compose(o.inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AB54D5A6A75E1", "submission_order": 1, "result": "AC", "execution_time": "1835 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AB828313FB12D", "submission_order": 1, "result": "WA", "execution_time": "1406 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AB828313FB12D", "submission_order": 2, "result": "WA", "execution_time": "1389 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 1, "result": "WA", "execution_time": "1257 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(n)\n    qc.compose(o, inplace=True)\n    qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 2, "result": "WA", "execution_time": "1265 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    qc.compose(o, inplace=True)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 3, "result": "WA", "execution_time": "1432 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.compose(o, inplace=True)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 4, "result": "WA", "execution_time": "1253 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.compose(o, inplace=True)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 5, "result": "WA", "execution_time": "1304 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 6, "result": "RE", "execution_time": "1172 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, x, inplace=True)\n    qc.z(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 7, "result": "RE", "execution_time": "1337 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, range(n), inplace=True)\n    qc.z(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(n)\n    qc.compose(o, range(n) inplace=True)\n    qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 9, "result": "RE", "execution_time": "1247 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(n)\n    qc.compose(o, [range(n)], inplace=True)\n    qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 10, "result": "WA", "execution_time": "1252 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(n)\n    qc.compose(o, inplace=True)\n    qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ABF5B7497970F", "submission_order": 11, "result": "AC", "execution_time": "1709 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    qc.h(n)\n    qc.compose(o, inplace=True)\n    qc.h(n)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AC1136671E6D8", "submission_order": 1, "result": "WA", "execution_time": "1249 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ACB7425985A24", "submission_order": 1, "result": "WA", "execution_time": "1308 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.compose(o, inplace=True)    \n    for i in range(n):\n        qc.cz(y[0], x[i])\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ACB7425985A24", "submission_order": 2, "result": "WA", "execution_time": "1261 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.compose(o, inplace=True)    \n    for i in range(n):\n        qc.x(y[0])\n        qc.cz(y[0], x[i])\n        qc.x(y[0])\n        qc.cz(y[0], x[i])\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ACB7425985A24", "submission_order": 3, "result": "WA", "execution_time": "1387 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.compose(o, inplace=True)    \n    for i in range(n):\n        qc.x(x[i])\n        qc.cz(y[0], x[i])\n        qc.x(x[i])\n        qc.cz(y[0], x[i])\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ACB7425985A24", "submission_order": 4, "result": "AC", "execution_time": "1730 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.compose(o, inplace=True)   \n    qc.z(y)\n    qc.compose(o, inplace=True)   \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ACB9E9D132E98", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    from qiskit import ClassicalRegister\n    c = ClassicalRegister(1)\n    circ = QuantumCircuit(y, c)\n    qc.compose(o, inplace=True)\n\n    if circ.measure(y, c) == 1:\n        x = -x\n\n    qc = QuantumCircuit(x, y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ACB9E9D132E98", "submission_order": 2, "result": "WA", "execution_time": "1391 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.compose(o, inplace=True)\n    c = QuantumRegister(1)\n    circ = QuantumCircuit(c)\n    circ.x(0)\n\n    if y == c:\n        x = -x\n\n    qc = QuantumCircuit(x, y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AD095F926380F", "submission_order": 1, "result": "WA", "execution_time": "1624 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AD095F926380F", "submission_order": 2, "result": "RE", "execution_time": "1345 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=Tr)\n    qc.z(y)\n    qc.cx(0, y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AD095F926380F", "submission_order": 3, "result": "RE", "execution_time": "1126 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=Tr)\n    qc.z(y)\n    qc.cx(x[0], y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AD095F926380F", "submission_order": 4, "result": "AC", "execution_time": "1646 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AD31D3002A631", "submission_order": 1, "result": "AC", "execution_time": "2005 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y[0])\n    qc.h(y[0])\n\n    qc.compose(o, inplace=True)\n\n    qc.h(y[0])\n    qc.x(y[0])\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AD42894DE43B2", "submission_order": 1, "result": "WA", "execution_time": "2006 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Apply the oracle O\n    qc.compose(o, inplace=True)\n    \n    # Apply a CNOT gate controlled by the first qubit of x (which represents f(x))\n    # and targeting the second qubit (y).\n    # We assume that the oracle has been designed such that the first qubit of x\n    # will represent f(x) after the oracle is applied.\n    qc.cx(x[0], y[0])  # CNOT gate: control = x[0], target = y[0]\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADA43D26F5631", "submission_order": 1, "result": "WA", "execution_time": "1184 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADA43D26F5631", "submission_order": 2, "result": "RE", "execution_time": "1187 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.x(n, n)\n \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADA43D26F5631", "submission_order": 3, "result": "AC", "execution_time": "2034 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADA91A93CE7D3", "submission_order": 1, "result": "WA", "execution_time": "1192 ms", "memory": "156 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.compose(o, inplace=True)\n    qc.cz(y, x[0])\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADA91A93CE7D3", "submission_order": 2, "result": "WA", "execution_time": "1468 ms", "memory": "156 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.compose(o, inplace=True)\n    qc.cz(y, x[0])\n    qc.compose(o, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADA91A93CE7D3", "submission_order": 3, "result": "WA", "execution_time": "1515 ms", "memory": "156 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.compose(o, inplace=True)\n    qc.mcp(np.pi, x, y) \n    qc.compose(o, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADA91A93CE7D3", "submission_order": 4, "result": "WA", "execution_time": "1251 ms", "memory": "156 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.compose(o, inplace=True)\n    qc.mcp(np.pi, x, y) \n    qc.compose(o.inverse(), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADA91A93CE7D3", "submission_order": 5, "result": "AC", "execution_time": "1882 ms", "memory": "156 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o.inverse(), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADCF04B195935", "submission_order": 1, "result": "WA", "execution_time": "2372 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADCF04B195935", "submission_order": 2, "result": "AC", "execution_time": "2288 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "ADDAE82CD7DA6", "submission_order": 1, "result": "AC", "execution_time": "2018 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.p(math.pi,y)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AE2FB90492BA8", "submission_order": 1, "result": "WA", "execution_time": "1431 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AE2FB90492BA8", "submission_order": 2, "result": "AC", "execution_time": "1698 ms", "memory": "156 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AE393D7DDDB60", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    You can apply oracle as follows:\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AE393D7DDDB60", "submission_order": 2, "result": "AC", "execution_time": "1769 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AE7DDA09D11B4", "submission_order": 1, "result": "AC", "execution_time": "1733 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AEB3B26196AB7", "submission_order": 1, "result": "WA", "execution_time": "2352 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y, z = QuantumRegister(n), QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y, z)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AEB3B26196AB7", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nform math import pi\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y, z)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cry(2*pi,y,x[i])\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AEB3B26196AB7", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nform math import pi\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y, z)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y)\n    qc.compose(o, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AEB3B26196AB7", "submission_order": 4, "result": "RE", "execution_time": "1515 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y, z)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        rc.cry(2*pi, y, x[i])\n    qc.compose(o, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AEB3B26196AB7", "submission_order": 5, "result": "RE", "execution_time": "1548 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y, z)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cry(2*pi, y, x[i])\n    qc.compose(o, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AEB3B26196AB7", "submission_order": 6, "result": "WA", "execution_time": "1658 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.cry(2*pi, y, x[i])\n    qc.compose(o, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AECEE625DF605", "submission_order": 1, "result": "RE", "execution_time": "1984 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(2)\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.h(2)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AECEE625DF605", "submission_order": 2, "result": "WA", "execution_time": "1944 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AECEE625DF605", "submission_order": 3, "result": "WA", "execution_time": "2529 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(0)\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AECEE625DF605", "submission_order": 4, "result": "WA", "execution_time": "1870 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AECEE625DF605", "submission_order": 5, "result": "AC", "execution_time": "2354 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.h(y)\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AED77C7696D56", "submission_order": 1, "result": "AC", "execution_time": "1675 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    qc.h(n)\n    qc.compose(o, inplace=True)\n    qc.h(n)\n    qc.x(n)\n \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF63245BC7C55", "submission_order": 1, "result": "RE", "execution_time": "1147 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y, z = QuantumRegister(n), QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.add_bits(z)\n    qc.compose(o, inplace=True)\n    qc.cx(n, n+1)\n    qc.cz(n+1, n)\n    qc.cx(n, n+1)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF63245BC7C55", "submission_order": 2, "result": "AC", "execution_time": "1700 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF802A717333C", "submission_order": 1, "result": "WA", "execution_time": "1391 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF802A717333C", "submission_order": 2, "result": "AC", "execution_time": "1806 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    qc.h(n)\n    qc.compose(o, inplace=True)\n    qc.h(n)\n    qc.x(n)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF9B40A8BD0E5", "submission_order": 1, "result": "RE", "execution_time": "1169 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.z(n)\n    qc.cx(n, n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF9B40A8BD0E5", "submission_order": 2, "result": "WA", "execution_time": "1528 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.z(n)\n    # qc.cx(n, n)\n\n\n \n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF9B40A8BD0E5", "submission_order": 3, "result": "RE", "execution_time": "1175 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.z(n)\n    qc.measure(n)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF9B40A8BD0E5", "submission_order": 4, "result": "RE", "execution_time": "1201 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.z(n)\n    qc.measure([n])\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF9B40A8BD0E5", "submission_order": 5, "result": "WA", "execution_time": "1421 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.x(n)\n    qc.z(n)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AF9B40A8BD0E5", "submission_order": 6, "result": "RE", "execution_time": "1221 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.add_bits(QuantumRegister(1))\n    qc.cx(n, n+1)\n    qc.z(n+1)\n    qc.cx(n, n+1)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AFAE7ED996E48", "submission_order": 1, "result": "WA", "execution_time": "2033 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(1)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AFAE7ED996E48", "submission_order": 2, "result": "AC", "execution_time": "2925 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(n)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AFC0510336571", "submission_order": 1, "result": "WA", "execution_time": "1344 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.z(x[0])\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AFC0510336571", "submission_order": 2, "result": "WA", "execution_time": "1354 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.cx(x[0],y)\n    qc.z(y)\n    qc.cx(x[0],y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AFC0510336571", "submission_order": 3, "result": "WA", "execution_time": "1279 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.cz(x[0], y)\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AFC0510336571", "submission_order": 4, "result": "WA", "execution_time": "1299 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B2", "user": "AFC0510336571", "submission_order": 5, "result": "WA", "execution_time": "1224 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0843D504F00A", "submission_order": 1, "result": "AC", "execution_time": "2028 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.ry(T[i]*2,i)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     T=[np.pi/6,np.pi/3,np.pi/2]\n#     qc = solve(3,T)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_B3", "user": "A0CC86C7395BF", "submission_order": 1, "result": "AC", "execution_time": "1680 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        theta = 2 * T[i]\n        qc.ry(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 1, "result": "WA", "execution_time": "1466 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    j=len(T)\n    for i in range(j):\n        qc.h(i)\n        qc.ry(T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 2, "result": "WA", "execution_time": "1250 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.ry(T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 3, "result": "WA", "execution_time": "1246 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.ry(2*T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 4, "result": "WA", "execution_time": "1349 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.rx(2*T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 5, "result": "WA", "execution_time": "1220 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.rx(T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 6, "result": "WA", "execution_time": "1237 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.rx(T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 7, "result": "WA", "execution_time": "1246 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.rz(T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 8, "result": "WA", "execution_time": "1186 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.p(T[i],i)\n        qc.h(i)\n        qc.p(T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 9, "result": "WA", "execution_time": "1518 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.p(2*T[i],i)\n        qc.h(i)\n        qc.p(2*T[i],i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 10, "result": "RE", "execution_time": "1232 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.p(2*T[i],i)\n        qc.h(i)\n        qc.p(pi,i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 11, "result": "WA", "execution_time": "1182 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.p(2*T[i],i)\n        qc.h(i)\n        qc.p(math.pi,i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 12, "result": "WA", "execution_time": "1557 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.p(T[i],i)\n        qc.h(i)\n        qc.p(math.pi/2,i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 13, "result": "WA", "execution_time": "1234 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.p(2*T[i],i)\n        qc.h(i)\n        qc.p(math.pi,i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 14, "result": "WA", "execution_time": "1201 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.p(T[i],i)\n        qc.h(i)\n        qc.p(math.pi/2,i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A0DCD8F86DE7C", "submission_order": 15, "result": "AC", "execution_time": "1632 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        qc.p(2*T[i],i)\n        qc.h(i)\n        qc.p(math.pi/2,i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A137A0983223C", "submission_order": 1, "result": "AC", "execution_time": "1722 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        # Aplicar una rotación Ry con ángulo 2*T[i] al qubit i\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A14D48EBB4012", "submission_order": 1, "result": "AC", "execution_time": "1818 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * T[i]  # Calcular el ángulo\n        qc.ry(theta, i)   #Aplicar rotacion\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A22E93140B158", "submission_order": 1, "result": "AC", "execution_time": "1924 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * T[i]\n        qc.u(theta, 0, 0, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A27514FDBF5F7", "submission_order": 1, "result": "WA", "execution_time": "1241 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(len(T)):\n        theta = 2 / T[i]\n        qc.ry(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A27514FDBF5F7", "submission_order": 2, "result": "AC", "execution_time": "2111 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(len(T)):\n        theta = 2 * T[i]\n        qc.ry(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A2768EB3CFEC3", "submission_order": 1, "result": "AC", "execution_time": "1592 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(theta=2*T[i], qubit=i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A33659B2EC51D", "submission_order": 1, "result": "AC", "execution_time": "2859 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in range(n):\n        qc.ry(T[_] * 2, _)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3461CE99739E", "submission_order": 1, "result": "AC", "execution_time": "1550 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3517DC737D7E", "submission_order": 1, "result": "AC", "execution_time": "1844 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = abs(T[i])*2\n        qc.ry(theta, i)\n        if T[i]<0:\n            qc.z(i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A37C73B975BD2", "submission_order": 1, "result": "AC", "execution_time": "2072 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3AF0F22548E5", "submission_order": 1, "result": "WA", "execution_time": "1261 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        qc.ry(t, qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3AF0F22548E5", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        qc.ry(2t, qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3AF0F22548E5", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        i = 2t\n        qc.ry(i, qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3AF0F22548E5", "submission_order": 4, "result": "AC", "execution_time": "1891 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        i = 2*t\n        qc.ry(i, qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3D113AD126AA", "submission_order": 1, "result": "RE", "execution_time": "1619 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i], 1)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3D113AD126AA", "submission_order": 2, "result": "AC", "execution_time": "1614 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 1, "result": "RE", "execution_time": "1337 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.S(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 2, "result": "RE", "execution_time": "1224 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.S(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 4, "result": "WA", "execution_time": "1198 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 5, "result": "WA", "execution_time": "1291 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(-2*T[i],i)\n        qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 6, "result": "WA", "execution_time": "1185 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(T[i],i)\n        qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 7, "result": "WA", "execution_time": "1524 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(T[i],i)\n        qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 8, "result": "WA", "execution_time": "1178 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.h(0)\n        qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 9, "result": "WA", "execution_time": "1485 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.h(i)\n        qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 10, "result": "WA", "execution_time": "1190 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(-2*T[i],i)\n        qc.h(i)\n        qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 11, "result": "WA", "execution_time": "1480 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(-2*T[i],i)\n        qc.h(i)\n        #qc.s(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 12, "result": "RE", "execution_time": "1360 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(-2*T[i],i)\n        qc.h(i)\n        qc.P(-math.pi/2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 13, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    theta=math.pi\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(-2*T[i],i)\n        qc.h(i)\n        qc.P(-theta/2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 14, "result": "WA", "execution_time": "1253 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    theta=math.pi\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(-2*T[i],i)\n        qc.h(i)\n        qc.p(-theta/2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 15, "result": "WA", "execution_time": "1252 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    theta=math.pi\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.h(i)\n        qc.p(-theta/2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 16, "result": "WA", "execution_time": "1258 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.h(i)\n        qc.s(i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3E84C483D974", "submission_order": 17, "result": "AC", "execution_time": "1583 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.rz(2*T[i],i)\n        qc.h(i)\n        qc.s(i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A3F9C76E7D9C4", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import , PhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.ry(T[i] * 2, i)\n\treturn qc\n'''"}
{"problem": "QPC003_B3", "user": "A3F9C76E7D9C4", "submission_order": 2, "result": "AC", "execution_time": "1871 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate, CXGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.ry(T[i] * 2, i)\n\treturn qc\n'''"}
{"problem": "QPC003_B3", "user": "A4D017E2B0E26", "submission_order": 1, "result": "AC", "execution_time": "1944 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A5312B6BABBEC", "submission_order": 1, "result": "AC", "execution_time": "1713 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.ry(2*T[i], i)\n \n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A59D5ED0349EF", "submission_order": 1, "result": "WA", "execution_time": "1422 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rx(T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A59D5ED0349EF", "submission_order": 2, "result": "AC", "execution_time": "1772 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A5BD5F6FDDAEF", "submission_order": 1, "result": "AC", "execution_time": "1754 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3, [0.1, 0.2, 0.3])\n    print(qc)\n'''"}
{"problem": "QPC003_B3", "user": "A5E5B4366C26E", "submission_order": 1, "result": "AC", "execution_time": "1997 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i, t in enumerate(T):\n        qc.ry(2 * t, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A6355235D5BA8", "submission_order": 1, "result": "AC", "execution_time": "1741 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A64BE1313F961", "submission_order": 1, "result": "AC", "execution_time": "1700 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        theta = T[i] * 2.0\n        qc.ry(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A696652727705", "submission_order": 1, "result": "AC", "execution_time": "1626 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A764343BF39A4", "submission_order": 1, "result": "RE", "execution_time": "1777 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i, r in enumerate(T):\n        qc.ry(i*2, r)\n        \n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A764343BF39A4", "submission_order": 2, "result": "AC", "execution_time": "2074 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(T[i]*2, i)\n        \n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A786AE92A3A4F", "submission_order": 1, "result": "RE", "execution_time": "1179 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    phi = 0\n    lam = np.pi\n    for i,t in enumarate(T):\n        theta = 2*t\n        qc.u(theta, phi, lam, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A786AE92A3A4F", "submission_order": 2, "result": "AC", "execution_time": "1764 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    phi = 0\n    lam = np.pi\n    for i,t in enumerate(T):\n        theta = 2*t\n        qc.u(theta, phi, lam, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A78CB44BB2B5C", "submission_order": 1, "result": "AC", "execution_time": "1611 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i], i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_B3", "user": "A799A7E7A0416", "submission_order": 1, "result": "RE", "execution_time": "1446 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.u(2*T[i], pi/2, 0)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A799A7E7A0416", "submission_order": 2, "result": "RE", "execution_time": "1278 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    for i in range(n):\n        mat = [[cos(T[i]), sin(T[i])],\n               [0,0]]\n        qc.UnitaryGate( mat , [i])\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A799A7E7A0416", "submission_order": 3, "result": "RE", "execution_time": "1240 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    for i in range(n):\n        #mat = [[cos(T[i]), sin(T[i])],\n        #       [0,0]]\n        #qc.UnitaryGate( mat , [i])\n        qc.rx(2*T[i])\n        qc.s(i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A799A7E7A0416", "submission_order": 4, "result": "AC", "execution_time": "1837 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Write your code here:\n    for i in range(n):\n        #mat = [[cos(T[i]), sin(T[i])],\n        #       [0,0]]\n        #qc.UnitaryGate( mat , [i])\n        qc.rx(2*T[i], i)\n        qc.s(i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A7B9ABD80D2DE", "submission_order": 1, "result": "WA", "execution_time": "2161 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rx(-2*T[i],i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A7B9ABD80D2DE", "submission_order": 2, "result": "WA", "execution_time": "2605 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(-2*T[i],i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A7B9ABD80D2DE", "submission_order": 3, "result": "AC", "execution_time": "2099 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A7B9E9EBA6985", "submission_order": 1, "result": "AC", "execution_time": "1611 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A80697C721F10", "submission_order": 1, "result": "RE", "execution_time": "1875 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(-T[i] * 2)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A80697C721F10", "submission_order": 2, "result": "WA", "execution_time": "1714 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(-T[i] * 2, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A80697C721F10", "submission_order": 3, "result": "AC", "execution_time": "2144 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A8167F44F015C", "submission_order": 1, "result": "AC", "execution_time": "1773 ms", "memory": "156 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A852ADAFA3AC0", "submission_order": 1, "result": "WA", "execution_time": "1485 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A852ADAFA3AC0", "submission_order": 2, "result": "AC", "execution_time": "1649 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A8A261F162E37", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in len(T)\n        qc.Ry(T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A8A261F162E37", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    j=0\n    # Write your code here:\n    for i in T\n        qc.Ry(i,j)\n        j+=1\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A8A261F162E37", "submission_order": 3, "result": "RE", "execution_time": "1687 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    j=0\n    # Write your code here:\n    for i in T:\n        qc.Ry(i,j)\n        j+=1\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A8A261F162E37", "submission_order": 4, "result": "WA", "execution_time": "1639 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    j=0\n    # Write your code here:\n    for i in T:\n        qc.ry(i,j)\n        j+=1\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A8A261F162E37", "submission_order": 5, "result": "AC", "execution_time": "1538 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    j=0\n    # Write your code here:\n    for i in T:\n        qc.ry(i*2,j)\n        j+=1\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A8A59478866E7", "submission_order": 1, "result": "AC", "execution_time": "1628 ms", "memory": "155 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.ry(T[i]*2, i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A8E7DB7B46F95", "submission_order": 1, "result": "AC", "execution_time": "1733 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n      qc.r(2*T[i], math.pi/2, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A92676D11D8CF", "submission_order": 1, "result": "AC", "execution_time": "1654 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A954ED5D118C4", "submission_order": 1, "result": "AC", "execution_time": "1671 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A9E0DE3245FE3", "submission_order": 1, "result": "WA", "execution_time": "1634 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],n-1-i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A9E0DE3245FE3", "submission_order": 2, "result": "TOE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "A9E0DE3245FE3", "submission_order": 3, "result": "AC", "execution_time": "2025 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AA3FC69511DAD", "submission_order": 1, "result": "WA", "execution_time": "1239 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AA3FC69511DAD", "submission_order": 2, "result": "AC", "execution_time": "2212 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AAE99BBE1E5D0", "submission_order": 1, "result": "AC", "execution_time": "2003 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i]*2, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AB129CCBBC6DD", "submission_order": 1, "result": "AC", "execution_time": "1739 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n \n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AB9323EB81695", "submission_order": 1, "result": "AC", "execution_time": "1643 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.u(2*T[i], 0, 0, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AB9546E4617A9", "submission_order": 1, "result": "WA", "execution_time": "1306 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AB9546E4617A9", "submission_order": 2, "result": "WA", "execution_time": "1401 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i], n - i - 1)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AB9546E4617A9", "submission_order": 3, "result": "WA", "execution_time": "1741 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i] * 2, n - i - 1)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AB9546E4617A9", "submission_order": 4, "result": "AC", "execution_time": "1716 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ABA620DAE1640", "submission_order": 1, "result": "AC", "execution_time": "1577 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for idx in range(0, n):\n        qc.ry(2*T[idx], idx)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ABC01F9E72DC6", "submission_order": 1, "result": "RE", "execution_time": "1212 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i,t in enumurate[T]:\n        qc.p(T*2,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ABC01F9E72DC6", "submission_order": 2, "result": "RE", "execution_time": "1176 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i,t in enumurate[T]:\n        qc.p(t*2,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ABC01F9E72DC6", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i,t in enumrate[T]:\n        qc.p(t*2,i)e\n\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ABC01F9E72DC6", "submission_order": 4, "result": "RE", "execution_time": "1132 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i,t in enumrate[T]:\n        qc.p(t*2,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ABC01F9E72DC6", "submission_order": 5, "result": "RE", "execution_time": "1156 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i,t in enumrate[T]:\n        qc.ry(t*2,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ABC01F9E72DC6", "submission_order": 6, "result": "RE", "execution_time": "1202 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i,t in enumerate[T]:\n        qc.ry(t*2,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ABC01F9E72DC6", "submission_order": 7, "result": "AC", "execution_time": "1642 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(len(T)):\n        qc.ry(T[i]*2,i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AC8BE1747A422", "submission_order": 1, "result": "AC", "execution_time": "1939 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = T[i]\n\n        qc.ry(2 * theta, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ACA6F779DD4CC", "submission_order": 1, "result": "WA", "execution_time": "1254 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(2*T[0],0)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ACA6F779DD4CC", "submission_order": 2, "result": "AC", "execution_time": "1542 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "ACD2F40A17A4E", "submission_order": 1, "result": "AC", "execution_time": "1748 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in range(n):\n        qc.ry(T[_] * 2, _)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AD894CE6F3B95", "submission_order": 1, "result": "AC", "execution_time": "1994 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AD9CA953B188A", "submission_order": 1, "result": "RE", "execution_time": "1216 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(i, T[i])\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AD9CA953B188A", "submission_order": 2, "result": "WA", "execution_time": "1621 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AD9CA953B188A", "submission_order": 3, "result": "WA", "execution_time": "1275 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(-T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AE7FF38748892", "submission_order": 1, "result": "AC", "execution_time": "1664 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i, t in enumerate(T):\n        qc.ry(2 * t, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AF208C2944A22", "submission_order": 1, "result": "AC", "execution_time": "2093 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i, t in enumerate(T):\n        qc.ry(2 * t, i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AF34C39917A2A", "submission_order": 1, "result": "WA", "execution_time": "1466 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.ry(T[a], a)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AF34C39917A2A", "submission_order": 2, "result": "AC", "execution_time": "2014 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for a in range(n):\n        qc.ry(2*T[a], a)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AF6886CBF86E9", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nfor i in range(n):\n        qc.h(i)\n        qc.p(2*T[i],i)\n        qc.h(i)\n        qc.p(math.pi/2,i) \n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AF708B462156E", "submission_order": 1, "result": "AC", "execution_time": "1929 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AF8036D523A53", "submission_order": 1, "result": "WA", "execution_time": "1581 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.ry(T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AF8036D523A53", "submission_order": 2, "result": "RE", "execution_time": "1235 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        # qc.h(i)\n        circuit.ry(2 * T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AF8036D523A53", "submission_order": 3, "result": "RE", "execution_time": "1155 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        circuit.ry(2 * T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AFB4AF265653C", "submission_order": 1, "result": "WA", "execution_time": "1785 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply RY gates to each qubit\n    for i in range(n):\n        qc.ry(T[i], i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B3", "user": "AFB4AF265653C", "submission_order": 2, "result": "AC", "execution_time": "2877 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        theta = T[i]\n        qc.ry(2 * theta, i)  # Apply rotation around Y-axis\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A03EE29B3FC6E", "submission_order": 1, "result": "AC", "execution_time": "2863 ms", "memory": "193 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    regx = QuantumRegister(n)\n    qc = QuantumCircuit(regx)\n\n    anc = QuantumRegister(n)\n    qc.add_register(anc)\n\n    def ccx_chain(n):\n        regx, anc = QuantumRegister(n), QuantumRegister(n)\n        qc = QuantumCircuit(regx, anc)\n\n        qc.x(regx)\n        for idx in range(len(regx)):\n            if idx == 0:\n                qc.cx(regx[0], anc[0])\n            else:\n                qc.ccx(regx[idx], anc[idx-1], anc[idx])\n\n        return qc\n\n    qc.compose(ccx_chain(n), inplace=True)\n    qc.z(anc[-1])\n    qc.compose(ccx_chain(n).inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A07E919157685", "submission_order": 1, "result": "RE", "execution_time": "1200 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(control_qubits=list(range(1,n)), target_qubits=0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A07E919157685", "submission_order": 2, "result": "AC", "execution_time": "1756 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(control_qubits=list(range(1,n)), target_qubit=0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A0A59C13659AB", "submission_order": 1, "result": "WA", "execution_time": "1674 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(1, n):\n        qc.x(i)\n        \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A0E6A2DD1D455", "submission_order": 1, "result": "RE", "execution_time": "1199 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.mcx(control_qubits=range(n-1), target_qubit=n-1, ctrl_state=0)\n    qc.x(n-1)\n    qc.z(n-1)\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A0E6A2DD1D455", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.mcx(control_qubits=list(range(n-1)), target_qubit=n-1, ctrl_state=0)\n    qc.x(n-1)\n    qc.z(n-1)\n    qc.x(n-)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A0E6A2DD1D455", "submission_order": 3, "result": "RE", "execution_time": "1541 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.x(range(n))\n    if n == 1:\n        qc.z(0)\n    else:\n        qc.h(n - 1)                \n        qc.mct(list(range(n - 1)), n - 1)  \n        qc.h(n - 1)               \n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A0E6A2DD1D455", "submission_order": 4, "result": "RE", "execution_time": "1177 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    aux = QuantumRegister(1)\n    qc.add_bits(aux)\n\n    qc.x(aux)\n    qc.h(aux)\n    qc.mcx(control_qubits=list(range(n)), target_qubit=aux, ctrl_state=0)\n    qc.h(aux)\n    qc.x(aux)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A0E6A2DD1D455", "submission_order": 5, "result": "RE", "execution_time": "1261 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    aux = QuantumRegister(1)\n    qc.add_bits(aux)\n\n    qc.x(aux)\n    qc.h(aux)\n    qc.mcx(control_qubits=list(range(n)), target_qubit=aux, ctrl_state=0)\n    qc.h(aux)\n    qc.x(aux)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1594EB6E3496", "submission_order": 1, "result": "RE", "execution_time": "1386 ms", "memory": "153 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.z(0)\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1594EB6E3496", "submission_order": 2, "result": "AC", "execution_time": "1863 ms", "memory": "155 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    for i in range(n):\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 1, "result": "WA", "execution_time": "1295 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 2, "result": "RE", "execution_time": "1168 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.mcz(range(n-1), n)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 3, "result": "RE", "execution_time": "1470 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.mcz(range(n-1), n-1)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 4, "result": "RE", "execution_time": "1211 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.mcz(range(n-1), n-1)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx([range(n-1)], n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx([range(n-1)], n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 7, "result": "WA", "execution_time": "1560 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx([range(n-1)], n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 8, "result": "WA", "execution_time": "1259 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcx([range(1,n)], 0)\n    qc.h(0)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 9, "result": "WA", "execution_time": "1202 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcx([range(n-1,0,-1)], 0)\n    qc.h(0)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 10, "result": "WA", "execution_time": "1230 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcx(list(range(1,n)), 0)\n    qc.h(0)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 11, "result": "WA", "execution_time": "1253 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 12, "result": "WA", "execution_time": "1626 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.barrier()\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.barrier()\n\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n\n    return qc.reverse_bits()\n'''"}
{"problem": "QPC003_B4", "user": "A17ABD36F589A", "submission_order": 13, "result": "AC", "execution_time": "1733 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n   \n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A18454EF46442", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    lists = []\n    for i in range(1,n):\n        lists.append(i)\n    qc.mcx(lists,0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A18454EF46442", "submission_order": 2, "result": "RE", "execution_time": "1644 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    lists = []\n    for i in range(1,n):\n        lists.append(i)\n    qc.mcx(list,0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A18454EF46442", "submission_order": 3, "result": "AC", "execution_time": "1602 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    lists = []\n    for i in range(1,n):\n        lists.append(i)\n    qc.mcx(lists,0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1CAC9B58C5DE", "submission_order": 1, "result": "WA", "execution_time": "1535 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1CAC9B58C5DE", "submission_order": 2, "result": "WA", "execution_time": "1400 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1CAC9B58C5DE", "submission_order": 3, "result": "WA", "execution_time": "1248 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1CAC9B58C5DE", "submission_order": 4, "result": "WA", "execution_time": "1511 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(1, n):\n        qc.cx(0, i) \n    \n    for i in range(1, n):\n        qc.z(i)\n    \n    \n\n    \n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1CAC9B58C5DE", "submission_order": 5, "result": "WA", "execution_time": "1282 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(1, n):\n        qc.cx(0, i) \n    \n    for i in range(1, n):\n        qc.z(i)\n    \n    for i in range(n):\n        qc.h(i)\n    \n    \n\n    \n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1CAC9B58C5DE", "submission_order": 6, "result": "WA", "execution_time": "1262 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(1, n):\n        qc.z(i)\n    \n    \n    \n\n    \n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1CCD725B5A6D", "submission_order": 1, "result": "RE", "execution_time": "1466 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(range(n))\n    qc.h(n - 1)\n    qc.mct(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1CCD725B5A6D", "submission_order": 2, "result": "RE", "execution_time": "1601 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(range(n))\n    qc.h(n - 1)\n    qc.cx(0, 1)\n    qc.tdg(1)\n    qc.cx(1, n - 1)\n    qc.t(1)\n    qc.cx(0, 1)\n    qc.tdg(1)\n    qc.cx(1, n - 1)\n    qc.t(1)\n    qc.h(n - 1)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1E3C172C42E5", "submission_order": 1, "result": "WA", "execution_time": "1221 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1E3C172C42E5", "submission_order": 2, "result": "WA", "execution_time": "1354 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A1E3C172C42E5", "submission_order": 3, "result": "AC", "execution_time": "1751 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A22CF470AD8F7", "submission_order": 1, "result": "AC", "execution_time": "1877 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    \n    qc.append(ZGate().control(n-1), range(n))\n    \n    for i in range(n):\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A289AF56C3304", "submission_order": 1, "result": "WA", "execution_time": "1613 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    array = list(range(1, n))\n\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(array,0)\n    qc.h(0)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A289AF56C3304", "submission_order": 2, "result": "WA", "execution_time": "1762 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    array = list(range(1, n))\n\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        # qc.x(i)\n    # qc.h(0)\n    qc.mcx(array,0)\n    # qc.h(0)\n    for i in range(n):\n        qc.h(i)\n        # qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A289AF56C3304", "submission_order": 3, "result": "WA", "execution_time": "1571 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    array = list(range(1, n))\n\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.mcx(array,0)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A289AF56C3304", "submission_order": 4, "result": "UGE", "execution_time": "1355 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef diffuser_matrix(n):\n    # Dimension of the matrix\n    dim = 2 ** n\n    \n    # Create |00...0><00...0| which is all zeros except the (0, 0) element\n    projector = np.zeros((dim, dim))\n    projector[0, 0] = 1\n    \n    # Construct the diffuser matrix: A = 2 * projector - I\n    diffuser = 2 * projector - np.eye(dim)\n    \n    return diffuser\n\ndef solve(n: int) -> QuantumCircuit:\n    array = list(range(0,n))\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.unitary(diffuser_matrix(n), array)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A289AF56C3304", "submission_order": 5, "result": "RE", "execution_time": "1177 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    array = list(range(0,n))\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n    # qc.unitary(diffuser_matrix(n), array)\n    qc.h(0)\n    qc.mcx(array,0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A289AF56C3304", "submission_order": 6, "result": "AC", "execution_time": "1758 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    array = list(range(1,n))\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n    # qc.unitary(diffuser_matrix(n), array)\n    qc.h(0)\n    qc.mcx(array,0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A293009B9F083", "submission_order": 1, "result": "RE", "execution_time": "1395 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (1 << i) & 0:\n            qc.x(i)\n    \n    qc.mcp(theta, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if not (1 << i) & 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A293009B9F083", "submission_order": 2, "result": "AC", "execution_time": "1773 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if not (1 << i) & 0:\n            qc.x(i)\n    \n    qc.mcp(math.pi, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if not (1 << i) & 0:\n            qc.x(i)\n            \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A2C268C620324", "submission_order": 1, "result": "AC", "execution_time": "2101 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qubits = list(range(n))\n\n    qc.x(qubits)\n    qc.mcp(pi, qubits[1:], 0)\n    qc.x(qubits)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A2FB781580BB0", "submission_order": 1, "result": "AC", "execution_time": "1640 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n\n    qc.h(n-1)  \n    qc.mcx(list(range(n-1)), n-1) \n    qc.h(n-1)  \n    \n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A31BB0C413501", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    control = [0] * n\n    for i in range(n):\n        control[i]=i\n    for i in range(n):\n        qc.x(i)\n    custom = qc.ZGate().control(n-1)\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, control)\n    for i in range(n):\n    qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A31BB0C413501", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    control = [0] * n\n    for i in range(n):\n        control[i]=i\n    for i in range(n):\n        qc.x(i)\n    custom = qc.ZGate().control(n-1)\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, control)\n    for i in range(n):\n    qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A31BB0C413501", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.x(i)\n    custom = qc.ZGate().control(n-1)\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n    qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A31BB0C413501", "submission_order": 4, "result": "RE", "execution_time": "1253 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.x(i)\n    custom = qc.ZGate().control(n-1)\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A31BB0C413501", "submission_order": 5, "result": "AC", "execution_time": "1654 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.x(i)\n\n    qc1 = QuantumCircuit(1)\n    qc1.z(0)\n    custom = qc1.to_gate().control(n-1)\n\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A36F75A2F23E5", "submission_order": 1, "result": "WA", "execution_time": "1559 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)  # Llevar superposición\n    qc.z(0) #Cambiar la fase de 0\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A36F75A2F23E5", "submission_order": 2, "result": "RE", "execution_time": "1180 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n)\n    for i in range(n):\n        qc.cz(n, i)\n    qc.measure(n, 0)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A3DBAFAF3FAAA", "submission_order": 1, "result": "WA", "execution_time": "1602 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    for i in range(n - 1):\n        qc.cz(i,i + 1)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A3DBAFAF3FAAA", "submission_order": 2, "result": "RE", "execution_time": "1506 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    for i in range(n):\n        qc.cz(i,i + 1)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A3DBAFAF3FAAA", "submission_order": 3, "result": "RE", "execution_time": "1505 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A3DBAFAF3FAAA", "submission_order": 4, "result": "AC", "execution_time": "1876 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A4074F7BCE0BC", "submission_order": 1, "result": "AC", "execution_time": "1753 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init = [0]*(2**n)\n    # init[1] = 1\n    # qc.initialize(init)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    qc.append(GlobalPhaseGate(math.pi))\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_B4", "user": "A42ED56912ADE", "submission_order": 1, "result": "AC", "execution_time": "2272 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(range(n))\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n\n    qc.x(range(n))\n    \n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A45A1F26B3573", "submission_order": 1, "result": "AC", "execution_time": "1691 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n    qc.h(n - 1)\n\n    if n == 2:\n        qc.cx(0, 1)\n    else:\n        qc.mcx(list(range(n - 1)), n - 1)\n\n    qc.h(n - 1)\n    for i in range(n):\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A49FA5AEB5511", "submission_order": 1, "result": "WA", "execution_time": "1246 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.cz(range(n - 1), n - 1)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A4FC170408444", "submission_order": 1, "result": "AC", "execution_time": "2034 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Paso 1: Aplicar puertas X a todos los qubits para convertir |00...0> en |11...1>\n    qc.x(range(n))\n    \n    # Paso 2: Aplicar una puerta Z controlada por todos los qubits\n    # Implementación de una puerta Z multi-controlada:\n    # - Aplicar una puerta H al último qubit\n    # - Aplicar una puerta MCX (Toffoli multi-controlada) con los n-1 primeros qubits como controles y el último como objetivo\n    # - Aplicar una puerta H al último qubit nuevamente\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)  # Multi-Controlled X gate\n    qc.h(n-1)\n    \n    # Paso 3: Aplicar nuevamente puertas X a todos los qubits para restaurar los estados originales\n    qc.x(range(n))\n    \n    return qc\n\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A5567382B9FB7", "submission_order": 1, "result": "WA", "execution_time": "1408 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1,n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A5E0CD35EEE73", "submission_order": 1, "result": "RE", "execution_time": "1697 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    aux = QuantumRegister(1)\n    qc.add_bits(aux)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.mcx(list(range(n)), aux[0])\n    qc.z(aux[0])\n    qc.mcx(list(range(n)), aux[0])\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A5E0CD35EEE73", "submission_order": 2, "result": "RE", "execution_time": "1234 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    aux = QuantumRegister(1)\n    qc.add_bits(aux)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.mcx(list(range(n)), aux[0])\n    qc.z(aux[0])\n    qc.mcx(list(range(n)), aux[0])\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A5E0CD35EEE73", "submission_order": 3, "result": "RE", "execution_time": "1193 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    aux = QuantumRegister(1)\n    qc.add_bits(aux)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.mcx(list(range(n)), n)\n    qc.z(n)\n    qc.mcx(list(range(n)), n)\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A5E0CD35EEE73", "submission_order": 4, "result": "AC", "execution_time": "1595 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    \n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n    \n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 1, "result": "RE", "execution_time": "1237 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcz([range(n-1)], n)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 2, "result": "RE", "execution_time": "1270 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.z(range(n))\n    qc.mcz([range(n-1)], n)\n    # qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 3, "result": "RE", "execution_time": "1382 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.z(range(n))\n    qc.mcz([range(n-1)], n)\n    # qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 4, "result": "WA", "execution_time": "1278 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    # qc.mcz([range(n-1)], n)\n    # qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 5, "result": "WA", "execution_time": "1218 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    # qc.mcz([range(n-1)], n)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 6, "result": "RE", "execution_time": "1403 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcp(math.pi, [range(n-1)], n)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 7, "result": "RE", "execution_time": "1289 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcp(math.pi/2, [range(n-1)], n)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 8, "result": "RE", "execution_time": "1251 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcp(math.pi, [range(n-1)], n)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 9, "result": "RE", "execution_time": "1189 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcz([range(n-1)], n)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 10, "result": "RE", "execution_time": "1232 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcp(math.pi, [range(n-1)], n)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 11, "result": "RE", "execution_time": "1172 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcp(math.pi/2, [range(n-1)], n)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 12, "result": "WA", "execution_time": "1287 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcp(math.pi/2, [range(n-1)], n - 1)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 13, "result": "WA", "execution_time": "1340 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcp(math.pi, [range(n-1)], n - 1)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 14, "result": "WA", "execution_time": "1265 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.z(range(n))\n    qc.mcp(math.pi, [range(n-1)], n - 1)\n    qc.z(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6C376E11CA44", "submission_order": 15, "result": "WA", "execution_time": "1405 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n    qc.mcp(math.pi, [range(n-1)], n - 1)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A6FBFF4142880", "submission_order": 1, "result": "WA", "execution_time": "1584 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A72A1025273BC", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.extensions import UnitaryGate\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gates to all qubits\n    qc.h(range(n))\n    \n    # Step 2: Apply the phase flip to the |0⟩ state\n    # This can be done by applying a multi-controlled Z gate\n    # First, apply X gates to all qubits to flip |0⟩ to |1⟩\n    qc.x(range(n))\n    # Then apply a multi-controlled Z gate\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)  # Multi-controlled X gate\n    qc.h(n-1)\n    # Finally, apply X gates again to flip back to |0⟩\n    qc.x(range(n))\n    \n    # Step 3: Apply Hadamard gates again to all qubits\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A72A1025273BC", "submission_order": 2, "result": "WA", "execution_time": "1885 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gates to all qubits to create superposition\n    qc.h(range(n))\n    \n    # Step 2: Apply the phase flip to the |0⟩ state\n    # This is equivalent to applying a multi-controlled Z gate\n    # To implement this, we use X gates and a multi-controlled X gate\n    # Flip all qubits to |1⟩ using X gates\n    qc.x(range(n))\n    # Apply a multi-controlled Z gate (using H gates and a multi-controlled X gate)\n    qc.h(n-1)  # Apply H to the last qubit\n    qc.mcx(list(range(n-1)), n-1)  # Multi-controlled X gate (Toffoli-like)\n    qc.h(n-1)  # Apply H again to the last qubit\n    # Flip all qubits back to |0⟩ using X gates\n    qc.x(range(n))\n    \n    # Step 3: Apply Hadamard gates again to all qubits\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A72A1025273BC", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.extensions import UnitaryGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gates to all qubits\n    qc.h(range(n))\n    \n    # Step 2: Apply the phase flip to the |0⟩ state\n    # This can be done by applying a multi-controlled Z gate\n    # First, apply X gates to all qubits to flip |0⟩ to |1⟩\n    qc.x(range(n))\n    # Then apply a multi-controlled Z gate\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)  # Multi-controlled X gate\n    qc.h(n-1)\n    # Finally, apply X gates again to flip back to |0⟩\n    qc.x(range(n))\n    \n    # Step 3: Apply Hadamard gates again to all qubits\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A72A1025273BC", "submission_order": 4, "result": "UGE", "execution_time": "2037 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the multi-qubit |0><0| projector scaled by 2 and subtract identity\n    qc.h(range(n))  # Apply Hadamard gates to all qubits\n    qc.append(oracle(n), range(n))  # Apply the custom oracle\n    qc.h(range(n))  # Apply Hadamard gates to all qubits again\n    \n    return qc\n\ndef oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Implement 2|0><0| - I\n    qc.x(range(n))  # Flip all qubits\n    qc.h(n - 1)  # Hadamard on last qubit\n    qc.mcx(list(range(n - 1)), n - 1)  # Multi-control Toffoli\n    qc.h(n - 1)  # Hadamard on last qubit\n    qc.x(range(n))  # Flip all qubits back\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A72A1025273BC", "submission_order": 5, "result": "WA", "execution_time": "2191 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply the identity matrix (which does nothing)\n    # We will implement 2|0><0| - I\n    \n    # Step 1: Apply an MCX (multi-controlled X) gate to flip the |0...0> state to |1...1>\n    qc.append(MCXGate(n-1), list(range(n-1)) + [n-1])\n    \n    # Step 2: Apply a Z-gate (phase shift) on the |1...1> state\n    qc.z(n-1)\n    \n    # Step 3: Apply the MCX gate again to revert the |0...0> state\n    qc.append(MCXGate(n-1), list(range(n-1)) + [n-1])\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A79D80936A483", "submission_order": 1, "result": "WA", "execution_time": "1555 ms", "memory": "166 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, 2**n):\n        qc.x(range(n))\n        qc.z(range(n))\n        qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A80E9FE0F08C5", "submission_order": 1, "result": "WA", "execution_time": "1350 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, 2**n):\n        bits: list[bool] = [bool(int(x)) for x in f\"{i:0{n}b}\"]\n        for j, bit in enumerate(bits):\n            if bit:\n                qc.x(j)\n        qc.h(range(n))\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(range(n))\n        for j, bit in enumerate(bits):\n            if bit:\n                qc.x(j)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A80E9FE0F08C5", "submission_order": 2, "result": "WA", "execution_time": "1243 ms", "memory": "155 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(2**n - 1):\n        bits: list[bool] = [bool(int(x)) for x in f\"{i:0{n}b}\"]\n        for j, bit in enumerate(bits):\n            if bit:\n                qc.x(j)\n        qc.h(range(n))\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(range(n))\n        for j, bit in enumerate(bits):\n            if bit:\n                qc.x(j)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve(3)\n    print(qc)\n'''"}
{"problem": "QPC003_B4", "user": "A81DAF875E88B", "submission_order": 1, "result": "RE", "execution_time": "1243 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\n\n# https://www.qcoder.jp/ja/contests/QPC002/submissions/f6eee4b0-4f58-4f8f-8af9-82d02ab32490\ndef solve(n: int, theta: float) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L = 0\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(ZGate, [0])\n    else:\n        qc.append(ZGate.control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A81DAF875E88B", "submission_order": 2, "result": "RE", "execution_time": "1161 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n# https://www.qcoder.jp/ja/contests/QPC002/submissions/f6eee4b0-4f58-4f8f-8af9-82d02ab32490\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    L = 0\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(ZGate, [0])\n    else:\n        qc.append(ZGate.control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A81DAF875E88B", "submission_order": 3, "result": "RE", "execution_time": "1231 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    L = 0\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(PhaseGate(math.pi), [0])\n    else:\n        qc.append(PhaseGate(math.pi).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A81DAF875E88B", "submission_order": 4, "result": "AC", "execution_time": "1692 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    L = 0\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(PhaseGate(math.pi), [0])\n    else:\n        qc.append(PhaseGate(math.pi).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A836851CC696D", "submission_order": 1, "result": "AC", "execution_time": "1913 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, PhaseGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A852FDF553923", "submission_order": 1, "result": "RE", "execution_time": "1364 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(2*pi, 0)\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A852FDF553923", "submission_order": 2, "result": "AC", "execution_time": "1832 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.ry(2*pi, 0)\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8801E093888F", "submission_order": 1, "result": "RE", "execution_time": "1374 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.mcx([0, 1, 2], 3)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8801E093888F", "submission_order": 2, "result": "AC", "execution_time": "1916 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.h(n-1)\n    array = list(range(n -1))\n    qc.mcx(array, n-1)\n    qc.h(n-1)\n    for i in range(n):\n        qc.x(i)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8CC11C88BA36", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     I = (-1)*np.identity(2**n)\n    # Write your code here:\n    I[0][0] = 1\n    ls = [i for i in range(n)]\n    qc.UnitaryGate(I, ls)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8CC11C88BA36", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     I = (-1)*np.identity(2**n)\n    # Write your code here:\n    I[0][0] = 1\n    ls = [i for i in range(n)]\n    qc.unitary(I, ls)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8CC11C88BA36", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n     I = (-1)*np.identity(2**n)\n    # Write your code here:\n    I[0][0] = 1\n    ls = [i for i in range(n)]\n    qc.unitary(I, ls)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8CC11C88BA36", "submission_order": 4, "result": "UGE", "execution_time": "1197 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    I = (-1)*np.identity(2**n)\n    # Write your code here:\n    I[0][0] = 1\n    ls = [i for i in range(n)]\n    qc.unitary(I, ls)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8CC11C88BA36", "submission_order": 5, "result": "UGE", "execution_time": "1405 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    I = (-1)*np.identity(2**n, dtype = int)\n    # Write your code here:\n    I[0][0] = 1\n    ls = [i for i in range(n)]\n    qc.unitary(I, ls)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 1, "result": "WA", "execution_time": "1221 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cz(0, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 2, "result": "WA", "execution_time": "1236 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 3, "result": "WA", "execution_time": "1329 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, n):\n        qc.z(i)\n        qc.cz(0, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 4, "result": "WA", "execution_time": "1439 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cz(0, i)\n    for i in range(n):\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 5, "result": "WA", "execution_time": "1249 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.z(i)\n    for i in range(1, n):\n        qc.cz(0, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 6, "result": "WA", "execution_time": "1568 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.z(i)\n    for i in range(1, n):\n        qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 7, "result": "WA", "execution_time": "1255 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.z(i)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cz(0, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n    qc.h(i)\n    qc.z(i)\n\n    for i in range(n):\n        qc.x(i)\n    qc.h(n-1)\n    qc.mcx(range(n-1), n-1)\n    qc.h(n-1)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 9, "result": "RE", "execution_time": "1257 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n        qc.z(i)\n\n    for i in range(n):\n        qc.x(i)\n    qc.h(n-1)\n    qc.mcx(range(n-1), n-1)\n    qc.h(n-1)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 10, "result": "RE", "execution_time": "1357 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.z(qubit)\n\n    for qubit in range(n - 1):\n        qc.h(qubit)\n\n    qc.append(MCXGate(n - 1), [i for i in range(n - 1)] + [n - 1])\n\n    for qubit in range(n - 1):\n        qc.h(qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A8FACFEB7E2FD", "submission_order": 11, "result": "WA", "execution_time": "1251 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.z(qubit)\n\n    for qubit in range(n - 1):\n        qc.h(qubit)\n\n    qc.append(MCXGate(n - 1), [i for i in range(n - 1)] + [n - 1])\n\n    for qubit in range(n - 1):\n        qc.h(qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A93F4583E5399", "submission_order": 1, "result": "RE", "execution_time": "1245 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i == 0:\n            qc.z(i)\n        else:\n            qc.mcz(list(range(i)), i)\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A93F4583E5399", "submission_order": 2, "result": "AC", "execution_time": "1795 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i == 0:\n            qc.z(i)\n        else:\n            qc.mcp(math.pi, list(range(i)), i)\n        qc.x(i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A9C90C3E0C7DD", "submission_order": 1, "result": "RE", "execution_time": "1218 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.ccz()\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A9C90C3E0C7DD", "submission_order": 2, "result": "WA", "execution_time": "1225 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(4*math.pi,list(range(n - 1)),n - 1)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "A9C90C3E0C7DD", "submission_order": 3, "result": "AC", "execution_time": "2106 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(math.pi,list(range(n - 1)),n - 1)\n    qc.z(0)\n    qc.x(0)\n    qc.z(0)\n    qc.x(0)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AA3F753A052D8", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def make_U_s(nqubits):\n    U_s = QuantumCircuit(nqubits)\n\n    ## 2|0><0| - I の実装\n    U_s.add_gate(to_matrix_gate(RZ(nqubits-1, 2*np.pi))) ## まず、位相(-1)を全ての状態に付与する。ゲート行列はarrary([[-1,0],[0,-1]])\n    U_s.add_gate( X(nqubits-1) )\n    ## 全てのi-th qubitが0の場合だけZゲートを作用させる\n    CnZ = to_matrix_gate(Z(nqubits-1))\n    for i in range(nqubits-1):\n        control_index = i\n        control_with_value = 0\n        CnZ.add_control_qubit(control_index, control_with_value)\n    U_s.add_gate( CnZ )\n    U_s.add_gate( X(nqubits-1) )\n\n    return U_s\n\n    qc.U_s\n\n\n\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AA3F753A052D8", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def make_U_s(nqubits):\n    U_s = QuantumCircuit(nqubits)\n\n    ## 2|0><0| - I の実装\n    U_s.add_gate(to_matrix_gate(RZ(nqubits-1, 2*np.pi))) ## まず、位相(-1)を全ての状態に付与する。ゲート行列はarrary([[-1,0],[0,-1]])\n    U_s.add_gate( X(nqubits-1) )\n    ## 全てのi-th qubitが0の場合だけZゲートを作用させる\n    CnZ = to_matrix_gate(Z(nqubits-1))\n    for i in range(nqubits-1):\n        control_index = i\n        control_with_value = 0\n        CnZ.add_control_qubit(control_index, control_with_value)\n    U_s.add_gate( CnZ )\n    U_s.add_gate( X(nqubits-1) )\n\n    return U_s\n\n    U_s(qc)\n\n\n\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AA3F753A052D8", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def make_U_s(nqubits):\n    U_s = QuantumCircuit(nqubits)\n\n    ## 2|0><0| - I の実装\n    U_s.add_gate(to_matrix_gate(RZ(nqubits-1, 2*np.pi))) ## まず、位相(-1)を全ての状態に付与する。ゲート行列はarrary([[-1,0],[0,-1]])\n    U_s.add_gate( X(nqubits-1) )\n    ## 全てのi-th qubitが0の場合だけZゲートを作用させる\n    CnZ = to_matrix_gate(Z(nqubits-1))\n    for i in range(nqubits-1):\n        control_index = i\n        control_with_value = 0\n        CnZ.add_control_qubit(control_index, control_with_value)\n    U_s.add_gate( CnZ )\n    U_s.add_gate( X(nqubits-1) )\n\n    return U_s\n\n    U_s.update_quantum_state(qc)\n\n\n\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AA3F753A052D8", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def make_U_s(nqubits):\n    U_s = QuantumCircuit(nqubits)\n\n    ## 2|0><0| - I の実装\n    U_s.add_gate(to_matrix_gate(RZ(nqubits-1, 2*np.pi))) ## まず、位相(-1)を全ての状態に付与する。ゲート行列はarrary([[-1,0],[0,-1]])\n    U_s.add_gate( X(nqubits-1) )\n    ## 全てのi-th qubitが0の場合だけZゲートを作用させる\n    CnZ = to_matrix_gate(Z(nqubits-1))\n    for i in range(nqubits-1):\n        control_index = i\n        control_with_value = 0\n        CnZ.add_control_qubit(control_index, control_with_value)\n    U_s.add_gate( CnZ )\n    U_s.add_gate( X(nqubits-1) )\n\n    return U_s\n    U_s = make_U_s(nqubits)\n    U_s.update_quantum_state(qc)\n\n\n\n \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AA6178047628D", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info.operators.operator import Operator\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    uni = np.identity(n) * -1\n    uni[0][0] = 1\n    operator = Operator(uni)\n    qc.append(operator, [_ for _ in range(n)])\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AA6178047628D", "submission_order": 2, "result": "AC", "execution_time": "1865 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.rz(2*np.pi, n-1)\n    qc.x(list(range(n)))\n\n    # multi-controlled Zゲート\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n\n    qc.x(list(range(n)))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AAB69C1CC77F9", "submission_order": 1, "result": "AC", "execution_time": "1668 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n    qc.mcp(pi, list(range(n - 1)), n - 1)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AADCC0A1FFB8F", "submission_order": 1, "result": "WA", "execution_time": "1241 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.cz(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AADCC0A1FFB8F", "submission_order": 2, "result": "RE", "execution_time": "1355 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n-1)\n    for i in range(n):\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AADCC0A1FFB8F", "submission_order": 3, "result": "AC", "execution_time": "1629 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n - 1)\n    for i in range(n):\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB018B4A9BD50", "submission_order": 1, "result": "RE", "execution_time": "1300 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.z(i)\n\n\n    qc.x(0)  \n    qc.h(0)  \n    qc.x(0)  \n    \n    \n    qc.mcry(2 * 3.14159, [i for i in range(n)], n)  \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB018B4A9BD50", "submission_order": 2, "result": "WA", "execution_time": "1217 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.z(i)\n\n    qc.h(range(n)) \n    qc.x(range(n))  \n    qc.h(range(n)) \n    qc.z(0)  \n    qc.h(range(n))  \n    qc.x(range(n))  \n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB018B4A9BD50", "submission_order": 3, "result": "WA", "execution_time": "1245 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(range(n)) \n    qc.h(range(n))\n    \n    qc.cz(0, 1) \n    if n > 2:\n        for i in range(2, n):\n            qc.cz(0, i) \n    qc.h(range(n))\n    \n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB018B4A9BD50", "submission_order": 4, "result": "RE", "execution_time": "1413 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(range(n))\n    \n    qc.x(range(n))\n    \n    qc.h(0)  \n    qc.mcx([0] + list(range(1, n)), n-1) \n    \n    qc.x(range(n))\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB35BCA829BFD", "submission_order": 1, "result": "UGE", "execution_time": "1175 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.x(i)\n    qc.mcp(pi, list(range(1, n)), 0)\n    for i in range(n):\n      qc.x(i)\n    phase = QuantumCircuit(n, global_phase=pi).to_gate()\n    qc.compose(phase, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB35BCA829BFD", "submission_order": 2, "result": "AC", "execution_time": "2161 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.x(i)\n    qc.mcp(pi, list(range(1, n)), 0)\n    for i in range(n):\n      qc.x(i)\n    qc.global_phase = pi\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i inrange(n-2):\n        qc.x(i+1)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i inrange(n-3):\n        qc.x(i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 3, "result": "WA", "execution_time": "1232 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        qc.x(i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 4, "result": "WA", "execution_time": "1270 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        qc.x(n-i-1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 5, "result": "RE", "execution_time": "1297 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        qc.z(i+1)\n        qc.x(i+1)\n        qc.z(i+1)\n        qx.x(i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 6, "result": "WA", "execution_time": "1422 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        qc.z(i+1)\n        qc.x(i+1)\n        qc.z(i+1)\n        qc.x(i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 7, "result": "WA", "execution_time": "1632 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    for i in range(n-2):\n        qc.z(i+1)\n        qc.x(i+1)\n        qc.z(i+1)\n        qc.x(i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 8, "result": "WA", "execution_time": "1667 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    for i in range(n-2):\n        qc.z(i+1)\n        qc.x(i+1)\n        qc.z(i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 9, "result": "WA", "execution_time": "1223 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    for i in range(n-2):\n        qc.z(i)\n        qc.x(i)\n        qc.z(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 10, "result": "WA", "execution_time": "1680 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    for i in range(n-2):\n        qc.z(i)\n        qc.x(i)\n        qc.z(i)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 11, "result": "WA", "execution_time": "1203 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    for i in range(n-2):\n        qc.z(i+1)\n        qc.x(i+1)\n        qc.z(i+1)\n        qc.x(i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AB5A0C9331224", "submission_order": 12, "result": "WA", "execution_time": "1243 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(0)\n    for i in range(n-1):\n        qc.z(i+1)\n        qc.x(i+1)\n        qc.z(i+1)\n        qc.x(i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ACA89EC4E01B9", "submission_order": 1, "result": "AC", "execution_time": "1693 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.z(0)\n\n    for i in range(1, n):\n        qc.x(range(i))\n\n        qc.h(i)\n        qc.mcx(list(range(i)), i, mode='noancilla')\n        qc.h(i)\n\n        qc.x(range(i))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ACC935D666009", "submission_order": 1, "result": "AC", "execution_time": "1835 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, controls, target)\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD090CA912A6C", "submission_order": 1, "result": "WA", "execution_time": "1194 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n - 1) \n    qc.x(n-1)\n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD090CA912A6C", "submission_order": 2, "result": "WA", "execution_time": "1226 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n - 1) \n    qc.x(n-1)\n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n    qc.z(0)\n\n    for i in range(n):\n        qc.x(i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD090CA912A6C", "submission_order": 3, "result": "AC", "execution_time": "1745 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n - 1) \n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n    qc.z(0)\n\n    for i in range(n):\n        qc.x(i)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD12F78255B2E", "submission_order": 1, "result": "WA", "execution_time": "1384 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.append(MCXGate(n-1), list(range(n)))\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD12F78255B2E", "submission_order": 2, "result": "WA", "execution_time": "1403 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.mcx(list(range(1,n)), 0)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 1, "result": "WA", "execution_time": "1635 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(MCXGate(n-1), list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 2, "result": "WA", "execution_time": "1276 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.mcp(math.pi, list(range(n-1)), n-1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 3, "result": "WA", "execution_time": "1306 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(range(1, n))\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n    qc.x(range(1, n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 4, "result": "WA", "execution_time": "1287 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 5, "result": "WA", "execution_time": "1257 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 6, "result": "WA", "execution_time": "1236 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 7, "result": "WA", "execution_time": "1405 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(0)\n    for i in range(1, n):\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 8, "result": "WA", "execution_time": "1273 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1) \n    qc.h(n-1)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AD1F93D3D471E", "submission_order": 9, "result": "UGE", "execution_time": "1253 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    gate = []\n    for i in range(2**n):\n        if i == 0:\n            gate.append([1]+[0]*(2**n-1))\n        else:\n            gate.append([0]*(i)+[-1]+[0]*(2**n-i-1))\n    qc.unitary(gate, [i for i in range(n)])\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ADE624EABCF16", "submission_order": 1, "result": "RE", "execution_time": "1265 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n      qc.x(i)\n    qc.mp(math.pi, list(range(n-1)), n-1)\n    for i in range(n):\n      qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ADE624EABCF16", "submission_order": 2, "result": "AC", "execution_time": "1815 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n      qc.x(i)\n    qc.mcp(math.pi, list(range(n-1)), n-1)\n    for i in range(n):\n      qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ADF5E1D8F1B44", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(x):\n        qc.x{i}\n    \n    qc.qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ADF5E1D8F1B44", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(x):\n        qc.x{i}\n    \n    qc.qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ADF5E1D8F1B44", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(x):\n        qc.x{i}\n    \n    qc.append(ZGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ADF5E1D8F1B44", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(x):\n        qc.x{i}\n    \n    qc.append(ZGate().control(n - 1), range(n))\n\n    for i in range(x):\n        qc.x{i}\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ADF5E1D8F1B44", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(x):\n        qc.x{i}\n    \n    qc.append(ZGate().control(n - 1), range(n))\n\n    for j in range(x):\n        qc.x{j}\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "ADF5E1D8F1B44", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x{i}\n    \n    qc.append(ZGate().control(n - 1), range(n))\n\n    for j in range(n):\n        qc.x{j}\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AE4229820E005", "submission_order": 1, "result": "AC", "execution_time": "1617 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AECE3B8C810CD", "submission_order": 1, "result": "RE", "execution_time": "1139 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(1, 1 << n):\n        for j in range(n):\n            if i >> j & 1:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if i >> j & 1:\n                qc.x(j)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AECE3B8C810CD", "submission_order": 2, "result": "WA", "execution_time": "1455 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import CHGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(1, 1 << n):\n        for j in range(n):\n            if i >> j & 1:\n                qc.x(j)\n        qc.append(ZGate().control(n - 1), range(n))\n        for j in range(n):\n            if i >> j & 1:\n                qc.x(j)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AF6D4F4F67472", "submission_order": 1, "result": "WA", "execution_time": "1928 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply a Hadamard gate to all qubits to create superposition\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply a phase shift of π to all qubits except the first one (|0> state)\n    for qubit in range(1, n):\n        qc.z(qubit)  # Z gate applies a phase of π to |1> state\n    \n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AF76A9C95D5A3", "submission_order": 1, "result": "RE", "execution_time": "1398 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for l in range(1, 2^n + 1):\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n        if n == 1:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n        for i in range(n):\n            if not ((l >> i) & 1):\n                qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AF7EA234BF691", "submission_order": 1, "result": "WA", "execution_time": "1894 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.rx(math.pi,0)\n    for i in range(n-1):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AF7EA234BF691", "submission_order": 2, "result": "AC", "execution_time": "2087 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.rx(2*math.pi,0)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B4", "user": "AF8A4CE86BE23", "submission_order": 1, "result": "RE", "execution_time": "1360 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate, XGate, YGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int, T) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.x(i)\n\tqc.append(ZGate().control(n - 1), list(range(n)))\n\tfor i in range(n):\n\t\tqc.x(i)\n\treturn qc\n'''"}
{"problem": "QPC003_B4", "user": "AF8A4CE86BE23", "submission_order": 2, "result": "AC", "execution_time": "1706 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate, XGate, YGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.x(i)\n\tqc.append(ZGate().control(n - 1), list(range(n)))\n\tfor i in range(n):\n\t\tqc.x(i)\n\treturn qc\n'''"}
{"problem": "QPC003_B5", "user": "A09513C6B2308", "submission_order": 1, "result": "RE", "execution_time": "1435 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef b4(qc: QuantumCircuit) -> None:\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A09513C6B2308", "submission_order": 2, "result": "RE", "execution_time": "1200 ms", "memory": "154 MiB", "code": "'''python\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A09513C6B2308", "submission_order": 3, "result": "AC", "execution_time": "1494 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A0ACB2E3C5B85", "submission_order": 1, "result": "AC", "execution_time": "2058 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, controls, target)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A0C69922D9FEF", "submission_order": 1, "result": "WA", "execution_time": "2139 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gates to create |ψ⟩\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply the Grover diffusion operator (2|ψ⟩⟨ψ| - I)\n    \n    # Apply Hadamard again\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply X gates\n    for i in range(n):\n        qc.x(i)\n    \n    # Multi-controlled Z gate\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    \n    # Apply X gates again\n    for i in range(n):\n        qc.x(i)\n    \n    # Apply Hadamard again\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A0E1BF54759FC", "submission_order": 1, "result": "AC", "execution_time": "1642 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    for i in range(n):\n        qc.x(i)\n    qc.h(n - 1)\n    if n == 2:\n        qc.cx(0, 1)\n    else:\n        qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A1C1751C3A0B6", "submission_order": 1, "result": "RE", "execution_time": "1536 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef reflect(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.composer(reflect(n), inplace = True)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A1C1751C3A0B6", "submission_order": 2, "result": "RE", "execution_time": "1599 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef reflect(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.compose(reflect(n), inplace=True)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A1C1751C3A0B6", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.libary import ZGate\n\ndef reflect(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.compose(reflect(n), inplace=True)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A1C1751C3A0B6", "submission_order": 4, "result": "AC", "execution_time": "1908 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef reflect(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n \n    return qc\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.h(range(n))\n    qc.compose(reflect(n), inplace=True)\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A226714A0484C", "submission_order": 1, "result": "AC", "execution_time": "1776 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.x(i)\n\n    qc1 = QuantumCircuit(1)\n    qc1.z(0)\n    custom = qc1.to_gate().control(n-1)\n\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A2693F66A5BFE", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef reflect(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n \n    return qc\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.h(range(n))\n    qc.compose(reflect(n), inplace=True)\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A35F592113D7E", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, Aer, transpile, assemble, execute\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(range(n))\n    \n    \n    qc.x(range(n))\n    \n    qc.h(0)  \n    qc.mcx(list(range(1, n)), 0)  \n    qc.h(0)  \n    \n    qc.x(range(n))\n\n    return qc\n\nif __name__ == \"__main__\":\n    n = 2  \n    qc = solve(n)\n    print(qc.draw())\n'''"}
{"problem": "QPC003_B5", "user": "A35F592113D7E", "submission_order": 2, "result": "WA", "execution_time": "1274 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CXGate\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n   \n    for qubit in range(n):\n        qc.h(qubit)\n\n    \n    qc.x(range(n))\n\n    \n    for qubit in range(n-1):\n        qc.cx(qubit, n-1)  \n\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A383B33647F39", "submission_order": 1, "result": "AC", "execution_time": "1583 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Paso 1: Aplicar puertas Hadamard a todos los qubits para crear la superposición uniforme\n    qc.h(range(n))\n    \n    # Paso 2: Aplicar puertas X a todos los qubits\n    qc.x(range(n))\n    \n    # Paso 3: Aplicar una puerta Z multi-controlada\n    # Esto se logra mediante:\n    # a. Aplicar una puerta Hadamard al último qubit\n    qc.h(n-1)\n    \n    # b. Aplicar una puerta MCX (multi-controlled X) con los n-1 primeros qubits como controles y el último como objetivo\n    controls = list(range(n-1))\n    target = n-1\n    qc.mcx(controls, target)\n    \n    # c. Aplicar nuevamente una puerta Hadamard al último qubit\n    qc.h(n-1)\n    \n    # Paso 4: Aplicar nuevamente puertas X a todos los qubits para revertir la transformación\n    qc.x(range(n))\n    \n    # Paso 5: Aplicar puertas Hadamard a todos los qubits nuevamente para volver a la base computacional\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A53FADA138B98", "submission_order": 1, "result": "WA", "execution_time": "1428 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n - 1)\n    for i in range(n):\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A53FADA138B98", "submission_order": 2, "result": "WA", "execution_time": "1353 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n - 1)\n    for i in range(n):\n        qc.h(0)\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.h(0)\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A53FADA138B98", "submission_order": 3, "result": "AC", "execution_time": "1650 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n - 1)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A57D39479B097", "submission_order": 1, "result": "AC", "execution_time": "1764 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef b4(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.z(0)\n\n    for i in range(1, n):\n        qc.x(range(i))\n\n        qc.h(i)\n        qc.mcx(list(range(i)), i, mode='noancilla')\n        qc.h(i)\n\n        qc.x(range(i))\n\n    return qc\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.h(range(n))\n    qc.compose(b4(n), inplace=True)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A5C9A42FA480C", "submission_order": 1, "result": "AC", "execution_time": "1977 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(range(n))\n    qc.x(range(n))\n\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A6699B2D619E8", "submission_order": 1, "result": "AC", "execution_time": "1623 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.h(range(n))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A6F200D480BFD", "submission_order": 1, "result": "WA", "execution_time": "1276 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # n量子ビットの回路を作成\n    \n    for i in range(n):\n        qc.h(i)\n    \n    qc.append(ZGate().control(n-1), range(n))\n    \n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A6F200D480BFD", "submission_order": 2, "result": "WA", "execution_time": "1451 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # n量子ビットの回路を作成\n    \n    qc.append(ZGate().control(n-1), range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A6F200D480BFD", "submission_order": 3, "result": "AC", "execution_time": "1621 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    L = 0\n    \n    for i in range(n):\n        qc.h(i)\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(PhaseGate(math.pi), [0])\n    else:\n        qc.append(PhaseGate(math.pi).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n            \n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A7AD6F7DC2D4F", "submission_order": 1, "result": "AC", "execution_time": "1821 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.x(range(n))\n    \n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n    \n    qc.x(range(n))\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A7F87DD7F8F5E", "submission_order": 1, "result": "RE", "execution_time": "1637 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    return diffusion_oracle(n)\n'''"}
{"problem": "QPC003_B5", "user": "A7F87DD7F8F5E", "submission_order": 2, "result": "AC", "execution_time": "1983 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    return diffusion_oracle(n)\n'''"}
{"problem": "QPC003_B5", "user": "A808C0D60B07F", "submission_order": 1, "result": "AC", "execution_time": "1750 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.rz(2*np.pi, n-1)\n    qc.x(list(range(n)))\n\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n\n    qc.x(list(range(n)))\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A92A50CEE1FD1", "submission_order": 1, "result": "AC", "execution_time": "1688 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(control_qubits=list(range(1,n)), target_qubit=0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "A9734A1CD4BE5", "submission_order": 1, "result": "AC", "execution_time": "1644 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate, XGate, YGate, ZGate\nfrom math import sqrt, acos, pi\n\ndef solve(n: int) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.h(range(n))\n\tqc.x(range(n))\n\tqc.h(n - 1)\n\tqc.mcx(list(range(n - 1)), n - 1)\n\tqc.h(n - 1)\n\tqc.x(range(n))\n\tqc.h(range(n))\n\treturn qc\n'''"}
{"problem": "QPC003_B5", "user": "A9A09566DCA8C", "submission_order": 1, "result": "WA", "execution_time": "1723 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Prepare the state |ψ⟩ = (1/sqrt(2^n)) * (|0⟩ + |1⟩ + ... + |(2^n-1)⟩)\n    # This is done by applying Hadamard gates to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Step 2: Apply the operator A = 2 |ψ⟩⟨ψ| - I\n    # We can implement |ψ⟩⟨ψ| using a series of controlled operations.\n    \n    # Create a controlled operation that flips the sign of the state |ψ⟩\n    # This can be done by applying a series of CNOT gates based on the state |ψ⟩\n    # The state |ψ⟩ is the equal superposition, so we can use the fact that\n    # we want to apply a negative sign to the |ψ⟩ state.\n    \n    # The matrix A can be implemented as follows:\n    # 1. Apply a Hadamard to create |ψ⟩\n    # 2. Apply a series of CNOTs to create the effect of |ψ⟩⟨ψ| and then adjust for the identity.\n    \n    # The effect of 2|ψ⟩⟨ψ| can be achieved by applying a phase flip to the |ψ⟩ state.\n    # We can use a multi-controlled Z gate to achieve this.\n    \n    # Apply a controlled-Z gate with all qubits as controls to flip the sign of |ψ⟩\n    # This is equivalent to applying a phase of -1 to the |ψ⟩ state.\n    qc.h(range(n))  # Apply Hadamard to all qubits to create |ψ⟩\n    qc.z(range(n))  # Apply Z gate to all qubits to flip the sign of |ψ⟩\n    qc.h(range(n))  # Apply Hadamard again to return to the computational basis\n    \n    # Step 3: The identity operation is already accounted for in the circuit.\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "AA0445310DDB5", "submission_order": 1, "result": "AC", "execution_time": "1889 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init = [0]*(2**n)\n    # init[2] = 1\n    # qc.initialize(init)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    qc.append(GlobalPhaseGate(math.pi))\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_B5", "user": "AA14E0F874826", "submission_order": 1, "result": "AC", "execution_time": "1744 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Gloverのゲートが出ることは対策済み\n\n    for i in range(n):#重ね合わせ状態を作る\n        qc.h(i)\n    \n    for j in range(n):#反転じゃい\n        qc.x(j)\n\n    # 欲しい状態だけz gateで反転\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1) \n    qc.h(n - 1)\n\n    \n    for k in range(n):#反転して戻しちゃえ\n        qc.x(k)\n    \n    for l in range(n):#Hadamrd反転じゃい\n        qc.h(l)\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "AA737B6C0A0B1", "submission_order": 1, "result": "AC", "execution_time": "1762 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    qc.x(range(n))\n    qc.mcp(pi, list(range(n - 1)), n - 1)\n    qc.x(range(n))\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "ABB8B1C4963C2", "submission_order": 1, "result": "RE", "execution_time": "1370 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    lists=[]\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n-1):\n        lists.append(i)\n    qc.mcz(lists,n-1)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "ABB8B1C4963C2", "submission_order": 2, "result": "RE", "execution_time": "1626 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    lists=[]\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n-1):\n        lists.append(i)\n    qc.mct(lists,n-1)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "ABB8B1C4963C2", "submission_order": 3, "result": "RE", "execution_time": "1180 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    lists=[]\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n-1):\n        lists.append(i)\n    qc.mct(lists,n-1)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "ABB8B1C4963C2", "submission_order": 4, "result": "WA", "execution_time": "1627 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    lists=[]\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n-1):\n        lists.append(i)\n    qc.cz(0,1)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "ABB8B1C4963C2", "submission_order": 5, "result": "WA", "execution_time": "1304 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    lists=[]\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n-1):\n        lists.append(i)\n    for i in range (1,n):\n        qc.cz(0,i)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "ACFA849B6BD35", "submission_order": 1, "result": "AC", "execution_time": "2589 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "AD1F0130A3320", "submission_order": 1, "result": "AC", "execution_time": "1719 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qubits = list(range(n))\n\n    qc.h(qubits)\n    qc.x(qubits)\n    qc.mcp(pi, qubits[1:], 0)\n    qc.x(qubits)\n    qc.h(qubits)\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "ADBED0D502ADD", "submission_order": 1, "result": "AC", "execution_time": "1788 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n      qc.h(i)\n    for i in range(n):\n      qc.x(i)\n    qc.mcp(math.pi, list(range(n-1)), n-1)\n    for i in range(n):\n      qc.x(i)\n    for i in range(n):\n      qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "ADE8B8971BAB7", "submission_order": 1, "result": "AC", "execution_time": "1721 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve1(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    \n    qc.append(ZGate().control(n-1), range(n))\n    \n    for i in range(n):\n        qc.x(i)\n \n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    qc.compose(solve1(n), inplace=True)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "AE1FCB04A20FB", "submission_order": 1, "result": "AC", "execution_time": "1642 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "AE7EDCACF1369", "submission_order": 1, "result": "RE", "execution_time": "1528 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.mcz(list(range(n-1)),n-1)\n    for i in range(n):\n        qc.x(i)   \n    for i in range(n):\n        qc.h(i)        \n    return qc\n'''"}
{"problem": "QPC003_B5", "user": "AE7EDCACF1369", "submission_order": 2, "result": "AC", "execution_time": "1701 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(math.pi,list(range(n-1)),n-1)\n    for i in range(n):\n        qc.x(i)   \n    for i in range(n):\n        qc.h(i)        \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A0B3005D03988", "submission_order": 1, "result": "AC", "execution_time": "1592 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef b5(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init = [0]*(2**n)\n    # init[2] = 1\n    # qc.initialize(init)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    qc.append(GlobalPhaseGate(math.pi))\n    for i in range(n):\n        qc.h(i)\n    return qc\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    qc.compose(b5(n), inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A1F798132E269", "submission_order": 1, "result": "RE", "execution_time": "1684 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.append(QFT(n), range(n))\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A1F798132E269", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.append(QFT(n), range(n))\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A1F798132E269", "submission_order": 3, "result": "WA", "execution_time": "1292 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CXGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.append(HGate(), [i])\n        for j in range(i+1, n):\n            qc.append(CXGate(), [i, j])\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.compose(qft(n), inplace=True)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A1F798132E269", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CPiGate\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.append(HGate(), [i])\n        for j in range(i+1, n):\n            qc.append(CPiGate(2**(j-i)), [i, j])\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.compose(qft(n), inplace=True)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A1F798132E269", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, CPiGate\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)  # Define the qc variable here\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.barrier()\n    qc.compose(o, inplace=True)\n    qc.barrier()\n    qc.compose(qft(n), inplace=True)\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A2B4AB1926478", "submission_order": 1, "result": "RE", "execution_time": "1776 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Prepare uniform superposition\n    for qubit in range(n):\n        qc.h(qubit)  # Apply Hadamard to each qubit\n    \n    # Step 2: Apply the oracle\n    qc.compose(o, inplace=True)\n    \n    # Step 3: Apply the diffusion operator\n    # Apply Hadamard to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply X gates to all qubits\n    for qubit in range(n):\n        qc.x(qubit)\n    \n    # Apply controlled-Z (CZ) gate\n    qc.h(n-1)  # Apply Hadamard to the last qubit\n    qc.mct(list(range(n-1)), n-1)  # Multi-controlled Toffoli (n-1 controls)\n    qc.h(n-1)  # Apply Hadamard to the last qubit again\n    \n    # Apply X gates to all qubits again\n    for qubit in range(n):\n        qc.x(qubit)\n    \n    # Apply Hadamard to all qubits again\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A2B4AB1926478", "submission_order": 2, "result": "WA", "execution_time": "1940 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply the oracle\n    qc.compose(o, inplace=True)\n    \n    # Apply Hadamard gates again to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A3BB9350E11B1", "submission_order": 1, "result": "AC", "execution_time": "1622 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n    qc.compose(o, inplace=True)\n\n    qc.h(range(n))\n    qc.x(range(n))\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n    qc.x(range(n))\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A4DBF7CEDB28C", "submission_order": 1, "result": "RE", "execution_time": "1346 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    num_iterations = int(np.floor(np.pi / 4 * np.sqrt(2**n)))\n\n    for _ in range(num_iterations):\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(range(n))\n        qc.h(range(n))\n\n        for qubit in range(n):\n            qc.cz(0, qubit)\n        \n        qc.h(range(n))\n        qc.x(range(n))\n        qc.h(range(n))\n\n        for qubit in range(n):\n            if (target >> qubit) & 1:\n                qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A564674417D49", "submission_order": 1, "result": "AC", "execution_time": "1600 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.h(range(n))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n    qc.compose(o, inplace=True)\n    qc.compose(refl(n), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A5A2A3E1164CE", "submission_order": 1, "result": "WA", "execution_time": "1220 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(5):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(n-1)\n        array = list(range(n -1))\n        qc.mcx(array, n-1)\n        qc.h(n-1)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A5A2A3E1164CE", "submission_order": 2, "result": "WA", "execution_time": "1220 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(10):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(n-1)\n        array = list(range(n -1))\n        qc.mcx(array, n-1)\n        qc.h(n-1)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A5A2A3E1164CE", "submission_order": 3, "result": "WA", "execution_time": "1340 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(20):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(n-1)\n        array = list(range(n -1))\n        qc.mcx(array, n-1)\n        qc.h(n-1)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A5A2A3E1164CE", "submission_order": 4, "result": "WA", "execution_time": "1360 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(100):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(n-1)\n        array = list(range(n -1))\n        qc.mcx(array, n-1)\n        qc.h(n-1)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A5A2A3E1164CE", "submission_order": 5, "result": "TLE", "execution_time": "3000 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for j in range(10000):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(n-1)\n        array = list(range(n -1))\n        qc.mcx(array, n-1)\n        qc.h(n-1)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A5E4EB4074999", "submission_order": 1, "result": "RE", "execution_time": "1510 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(math.pi,list(range(n-1)),n-1)\n    for i in range(n):\n        qc.x(i)   \n    for i in range(n):\n        qc.h(i)        \n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A5E4EB4074999", "submission_order": 2, "result": "AC", "execution_time": "1558 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(math.pi,list(range(n-1)),n-1)\n    for i in range(n):\n        qc.x(i)   \n    for i in range(n):\n        qc.h(i)        \n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A6088A7EE11F6", "submission_order": 1, "result": "AC", "execution_time": "1979 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate, HGate\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tqc.h(range(n))\n\tqc.compose(o, inplace=True)\n\tqc.h(range(n))\n\tqc.x(range(n))\n\tqc.h(n - 1)\n\tqc.mcx(list(range(n - 1)), n - 1)\n\tqc.h(n - 1)\n\tqc.x(range(n))\n\tqc.h(range(n))\n\treturn qc\n'''"}
{"problem": "QPC003_B6", "user": "A6397EEC0C500", "submission_order": 1, "result": "WA", "execution_time": "1256 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef preparation(targets: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(len(targets))\n    qc.h(targets)\n    return qc\n\n\ndef reflection(qc, targets: list[int]):\n    o = preparation(targets)\n\n    qc.compose(o.inverse(), inplace=True)\n    qc.x(targets)\n    qc.mcp(pi, targets[:-1], targets[-1])\n    qc.x(targets)\n    qc.compose(o, inplace=True)\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    prep = preparation(list(range(n)))\n    oracle = o\n\n    qc = QuantumCircuit(n)\n    qc.compose(prep, inplace=True)\n    qc.compose(oracle, inplace=True)\n    qc.compose(prep, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A6397EEC0C500", "submission_order": 2, "result": "AC", "execution_time": "1621 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef preparation(targets: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(len(targets))\n    qc.h(targets)\n    return qc\n\n\ndef reflection(qc, targets: list[int]):\n    o = preparation(targets)\n\n    qc.compose(o.inverse(), inplace=True)\n    qc.x(targets)\n    qc.mcp(pi, targets[:-1], targets[-1])\n    qc.x(targets)\n    qc.compose(o, inplace=True)\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    prep = preparation(list(range(n)))\n    oracle = o\n\n    qc = QuantumCircuit(n)\n    qc.compose(prep, inplace=True)\n\n    qc.compose(oracle, inplace=True)\n    reflection(qc, list(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A64D28FBD05AF", "submission_order": 1, "result": "RE", "execution_time": "1673 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for _ in range(3):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion_oracle(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A64D28FBD05AF", "submission_order": 2, "result": "WA", "execution_time": "1781 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for _ in range(3):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion_oracle(n), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A64D28FBD05AF", "submission_order": 3, "result": "AC", "execution_time": "2064 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for _ in range(10):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion_oracle(n), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A673AC1225EFE", "submission_order": 1, "result": "AC", "execution_time": "1714 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    qc.compose(o, inplace=True)\n\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    if n == 1:\n        qc.z(0)\n    elif n == 2:\n        qc.h(n - 1)\n        qc.cx(0, 1)\n        qc.h(n - 1)\n    else:\n        qc.h(n - 1)\n        qc.mcx(list(range(n - 1)), n - 1)\n        qc.h(n - 1)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A7D9AE7DE96BC", "submission_order": 1, "result": "AC", "execution_time": "2568 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.h(range(n))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n    qc.compose(o, inplace=True)\n    qc.compose(refl(n), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A81729EF568E5", "submission_order": 1, "result": "AC", "execution_time": "1844 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve1(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    \n    qc.append(ZGate().control(n-1), range(n))\n    \n    for i in range(n):\n        qc.x(i)\n \n    return qc\n\ndef solve2(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    qc.compose(solve1(n), inplace=True)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    qc.compose(solve2(n), inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A88FC06F93189", "submission_order": 1, "result": "AC", "execution_time": "1647 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffuser(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    niter = math.floor(math.pi/4  * math.sqrt(2**n))\n    diff = diffuser(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(niter):\n        qc.compose(o, inplace=True)\n        qc.compose(diff, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 1, "result": "WA", "execution_time": "1441 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.compose(o,inplace=True)\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 2, "result": "WA", "execution_time": "1354 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.compose(o,inplace=True)\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    qc.compose(o,inplace=True)\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    qc.compose(o,inplace=True)\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    qc.compose(o,inplace=True)\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 3, "result": "WA", "execution_time": "1408 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    for _ in range(math.floor(math.pi/4*math.sqrt(2**n))):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n            qc.x(i)\n        qc.compose(o,inplace=True)\n        for i in range(n):\n            qc.x(i)\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 4, "result": "WA", "execution_time": "1260 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    for _ in range(9):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n            qc.x(i)\n        qc.compose(o,inplace=True)\n        for i in range(n):\n            qc.x(i)\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 5, "result": "WA", "execution_time": "1225 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  # type: ignore\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    for _ in range(math.floor(math.pi/4*math.sqrt(2**n))):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 6, "result": "WA", "execution_time": "1170 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  # type: ignore\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 7, "result": "WA", "execution_time": "1343 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  # type: ignore\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    for _ in range(5):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 8, "result": "WA", "execution_time": "1521 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  # type: ignore\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    for _ in range(25):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 9, "result": "WA", "execution_time": "1477 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  # type: ignore\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    # Grover's algorithm\n    for _ in range(math.floor(math.pi/4*math.sqrt(2**n/2))):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 10, "result": "WA", "execution_time": "1256 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  # type: ignore\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    # Grover's algorithm\n    for _ in range(6):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 11, "result": "WA", "execution_time": "1419 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  # type: ignore\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    # Grover's algorithm\n    for _ in range(math.floor(math.pi/4*math.sqrt(n))):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 12, "result": "WA", "execution_time": "1281 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit  # type: ignore\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init H\n    for i in range(n):\n        qc.h(i)\n    # Grover's algorithm\n    for _ in range(2):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "A8A9D79592E9D", "submission_order": 13, "result": "AC", "execution_time": "1562 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Apply Hadamard gate to all qubits to create superposition\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply Grover's algorithm with the necessary number of iterations\n    iterations = math.floor(math.pi / 4 * math.sqrt(2 ** n))\n    for _ in range(iterations):\n        # Apply the oracle\n        qc.compose(o, inplace=True)\n        \n        # Diffusion operator\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        \n        # Apply a multi-controlled Z gate\n        qc.h(0)\n        qc.mcx(list(range(1, n)), 0)  # Apply controlled-Z\n        qc.h(0)\n        \n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA1131E558C84", "submission_order": 1, "result": "WA", "execution_time": "2289 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n))\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA1131E558C84", "submission_order": 2, "result": "AC", "execution_time": "1947 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n))\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA7126FBC66AD", "submission_order": 1, "result": "RE", "execution_time": "1157 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, controls, target)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(range(n))\n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion(n), inplace = True)\n\n        \n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA7126FBC66AD", "submission_order": 2, "result": "RE", "execution_time": "1161 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, controls, target)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(range(n))\n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion(n), inplace = True)\n    \n    qc.measure_all()\n\n        \n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA7126FBC66AD", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion:\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, controls, target)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(range(n))\n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion, inplace = True)\n    \n    \n\n        \n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA7126FBC66AD", "submission_order": 4, "result": "RE", "execution_time": "1231 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, controls, target)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(range(n))\n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion(n), inplace = True)\n    \n\n\n        \n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA7126FBC66AD", "submission_order": 5, "result": "RE", "execution_time": "1246 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, controls, target)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(range(n))\n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion(n), inplace = True)\n    \n    qc.measure_all()\n\n        \n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA7126FBC66AD", "submission_order": 6, "result": "AC", "execution_time": "1666 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    qc = QuantumCircuit(n)\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, controls, target)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(range(n))\n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion(n), inplace = True)\n        \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA893E1F1CB9E", "submission_order": 1, "result": "RE", "execution_time": "1194 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffuser(n):\n    qc.h(range(n))\n    qc.rz(2*np.pi, n-1)\n    qc.x(list(range(n)))\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    qc.x(list(range(n)))\n    qc.h(range(n))\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(0.8 * n)):\n        qc.compose(o, inplace=True)\n        qc.diffuser()\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA893E1F1CB9E", "submission_order": 2, "result": "RE", "execution_time": "1234 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffuser(n):\n    qc.h(range(n))\n    qc.rz(2*np.pi, n-1)\n    qc.x(list(range(n)))\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    qc.x(list(range(n)))\n    qc.h(range(n))\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(0.8 * n)):\n        qc.compose(o, inplace=True)\n        qc.diffuser()\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AA893E1F1CB9E", "submission_order": 3, "result": "AC", "execution_time": "1903 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(0.8 * n)):\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.rz(2*np.pi, n-1)\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AAA5F757603D6", "submission_order": 1, "result": "AC", "execution_time": "1723 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Create uniform superposition\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Apply Grover iterations\n    # For the required probability 4/2^n, we need approximately 1-2 iterations\n    num_iterations = max(1, int(3.14159 / 4 * (2**n)**0.5 * 0.5))\n    \n    for _ in range(num_iterations):\n        # Apply oracle\n        qc.compose(o, inplace=True)\n        \n        # Apply diffusion operator (amplitude amplification about uniform superposition)\n        # This is 2|s><s| - I where |s> is uniform superposition\n        \n        # Transform back to computational basis\n        for i in range(n):\n            qc.h(i)\n        \n        # Flip phase of |0> state\n        qc.x(range(n))  # NOT all qubits\n        if n == 1:\n            qc.z(0)\n        else:\n            # Multi-controlled Z gate\n            qc.h(n-1)\n            qc.mcx(list(range(n-1)), n-1)\n            qc.h(n-1)\n        qc.x(range(n))  # NOT all qubits back\n        \n        # Transform back to superposition basis  \n        for i in range(n):\n            qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AAAC1A252D744", "submission_order": 1, "result": "AC", "execution_time": "1733 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    for _ in range(2):\n        qc.compose(o, inplace=True)\n\n        qc.h(range(n))\n        qc.x(range(n))\n        \n        qc.h(n - 1)\n        qc.mcx(list(range(n - 1)), n - 1)\n        qc.h(n - 1)\n        \n        qc.x(range(n))\n        qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "ABB57989A21AE", "submission_order": 1, "result": "RE", "execution_time": "1285 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Gloverのアルゴリズム\n    \n    #重ね合わせ合わせ状態にする\n    for i in range(n):\n        qc.h(qubit)\n\n    #反復回数計算\n    itr = int(2 ** (n / 2))\n\n    #反復開始！撃てぇええええ！\n    for _ in range(itr):\n        #欲しい状態だけ反転させる\n        qc.compose(o, inplace=True)\n\n        #アダマールゲートを作用させる\n        for i in range(n):\n            qc.h(i)\n\n        #X gate装填！ビットフリップ！\n        for i in range(n):\n            qc.x(i)\n\n        #おりゃあ増幅反転じゃい！\n        qc.h(n - 1)\n        qc.mcx(list(range(n - 1)), n - 1)\n        qc.h(n - 1)\n\n        #Xゲート反転じゃい！\n        for qubit in range(n):\n            qc.x(qubit)\n\n        #重ね合わせ解除！\n        for qubit in range(n):\n            qc.h(qubit)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "ABB57989A21AE", "submission_order": 2, "result": "RE", "execution_time": "1288 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Gloverのアルゴリズム\n    \n    #重ね合わせ合わせ状態にする\n    for i in range(n):\n        qc.h(qubit)\n\n    #反復回数計算\n    itr = int(2 ** (n / 2))\n\n    #反復開始！撃てぇええええ！\n    for k in range(itr):\n        #欲しい状態だけ反転させる\n        qc.compose(o, inplace=True)\n\n        #アダマールゲートを作用させる\n        for i in range(n):\n            qc.h(i)\n\n        #X gate装填！ビットフリップ！\n        for i in range(n):\n            qc.x(i)\n\n        #おりゃあ増幅反転じゃい！\n        qc.h(n - 1)\n        qc.mcx(list(range(n - 1)), n - 1)\n        qc.h(n - 1)\n\n        #Xゲート反転じゃい！\n        for i in range(n):\n            qc.x(i)\n\n        #重ね合わせ解除！\n        for qubit in range(n):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "ABB57989A21AE", "submission_order": 3, "result": "RE", "execution_time": "1209 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Gloverのアルゴリズム\n    \n    #重ね合わせ合わせ状態にする\n    for i in range(n):\n        qc.h(qubit)\n\n    #反復回数計算\n    itr = int(2 ** (n / 2))\n\n    #反復開始！撃てぇええええ！\n    for k in range(itr):\n        #欲しい状態だけ反転させる\n        qc.compose(o, inplace=True)\n\n        #アダマールゲートを作用させる\n        for i in range(n):\n            qc.h(i)\n\n        #X gate装填！ビットフリップ！\n        for i in range(n):\n            qc.x(i)\n\n        #おりゃあ増幅反転じゃい！\n        qc.h(n - 1)\n        qc.mcx(list(range(n - 1)), n - 1)\n        qc.h(n - 1)\n\n        #Xゲート反転じゃい！\n        for i in range(n):\n            qc.x(i)\n\n        #重ね合わせ解除！\n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "ABB57989A21AE", "submission_order": 4, "result": "AC", "execution_time": "1917 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Gloverのアルゴリズム\n    \n    #重ね合わせ合わせ状態にする\n    for i in range(n):\n        qc.h(i)\n\n    #反復回数計算\n    itr = int(2 ** (n / 2))\n\n    #反復開始！撃てぇええええ！\n    for k in range(itr):\n        #欲しい状態だけ反転させる\n        qc.compose(o, inplace=True)\n\n        #アダマールゲートを作用させる\n        for i in range(n):\n            qc.h(i)\n\n        #X gate装填！ビットフリップ！\n        for i in range(n):\n            qc.x(i)\n\n        #おりゃあ増幅反転じゃい！\n        qc.h(n - 1)\n        qc.mcx(list(range(n - 1)), n - 1)\n        qc.h(n - 1)\n\n        #Xゲート反転じゃい！\n        for i in range(n):\n            qc.x(i)\n\n        #重ね合わせ解除！\n        for i in range(n):\n            qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "ABF6543CBCFED", "submission_order": 1, "result": "AC", "execution_time": "1739 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Paso 1: Aplicar puertas Hadamard a todos los qubits para crear la superposición uniforme\n    qc.h(range(n))\n    \n    # Paso 2: Aplicar el oráculo O\n    qc.compose(o, inplace=True)\n    \n    # Paso 3: Aplicar el operador de difusión\n    # 3a: Aplicar puertas Hadamard a todos los qubits\n    qc.h(range(n))\n    \n    # 3b: Aplicar puertas X a todos los qubits\n    qc.x(range(n))\n    \n    # 3c: Aplicar una puerta Z multi-controlada\n    # Para implementar una puerta Z multi-controlada:\n    # - Aplicar una puerta Hadamard al último qubit\n    qc.h(n-1)\n    \n    # - Aplicar una puerta MCX (multi-controlled X) con los n-1 primeros qubits como controles y el último como objetivo\n    controls = list(range(n-1))\n    target = n-1\n    qc.mcx(controls, target)\n    \n    # - Aplicar nuevamente una puerta Hadamard al último qubit\n    qc.h(n-1)\n    \n    # 3d: Aplicar puertas X a todos los qubits\n    qc.x(range(n))\n    \n    # 3e: Aplicar puertas Hadamard a todos los qubits nuevamente\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AC2377F87EEBC", "submission_order": 1, "result": "RE", "execution_time": "1181 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, MCXGate\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for qubit in range(n):\n        qc.h(qubit)\n\n    qc.compose(o, inplace=True)\n\n    for qubit in range(n):\n        qc.h(qubit)\n\n    for qubit in range(n):\n        qc.x(qubit)\n\n    qc.mcx(list(range(n)), n-1)  \n\n    for qubit in range(n):\n        qc.x(qubit)\n\n    for qubit in range(n):\n        qc.h(qubit)\n\n    iterations = int(np.pi / 4 * np.sqrt(2**n))\n    for _ in range(iterations):\n        qc.compose(o, inplace=True) \n        for qubit in range(n):\n            qc.h(qubit)\n        for qubit in range(n):\n            qc.x(qubit)\n        qc.mcx(list(range(n)), n-1)  \n        for qubit in range(n):\n            qc.x(qubit)\n        for qubit in range(n):\n            qc.h(qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AD4ECF323B5D1", "submission_order": 1, "result": "WA", "execution_time": "1818 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # how to do the Grover rotations lol\n    for i in range(n):\n        qc.h(i)\n\n    for _ in range(4):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(0)\n        qc.mcx(control_qubits=list(range(1,n)), target_qubit=0)\n        qc.h(0)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AD4ECF323B5D1", "submission_order": 2, "result": "WA", "execution_time": "1621 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # how to do the Grover rotations lol\n    for i in range(n):\n        qc.h(i)\n\n    for _ in range(5):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(0)\n        qc.mcx(control_qubits=list(range(1,n)), target_qubit=0)\n        qc.h(0)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AD4ECF323B5D1", "submission_order": 3, "result": "WA", "execution_time": "1650 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # how to do the Grover rotations lol\n    for i in range(n):\n        qc.h(i)\n\n    for _ in range(6):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(0)\n        qc.mcx(control_qubits=list(range(1,n)), target_qubit=0)\n        qc.h(0)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AD4ECF323B5D1", "submission_order": 4, "result": "AC", "execution_time": "1568 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # how to do the Grover rotations lol\n    for i in range(n):\n        qc.h(i)\n\n    for _ in range(10):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.h(0)\n        qc.mcx(control_qubits=list(range(1,n)), target_qubit=0)\n        qc.h(0)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AD61132C591F4", "submission_order": 1, "result": "AC", "execution_time": "1707 ms", "memory": "156 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.h(i)\n\n    for _ in range(int(np.sqrt(n))):\n        qc.compose(o, inplace=True)\n    \n        for i in range(n):\n            qc.h(i)\n            qc.x(i)\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        for i in range(n):\n            qc.x(i)\n            qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "ADF3D4DB8C950", "submission_order": 1, "result": "AC", "execution_time": "1583 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qubits = list(range(n))\n\n    qc.h(qubits)\n\n    qc.compose(o, inplace=True)\n\n    qc.h(qubits)\n    qc.x(qubits)\n    qc.mcp(pi, qubits[1:], 0)\n    qc.x(qubits)\n    qc.h(qubits)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AF550BE3721C1", "submission_order": 1, "result": "RE", "execution_time": "1890 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n\ndef b5(qc: QuantumCircuit) -> None:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    b5(qc)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AF550BE3721C1", "submission_order": 2, "result": "WA", "execution_time": "1763 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n\ndef b5(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    b5(qc)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AF550BE3721C1", "submission_order": 3, "result": "AC", "execution_time": "1757 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n\ndef b5(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(o, inplace=True)\n    b5(qc)\n\n    return qc\n'''"}
{"problem": "QPC003_B6", "user": "AF5D71FD29034", "submission_order": 1, "result": "AC", "execution_time": "1642 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import PhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n#https://www.qcoder.jp/ja/contests/QPC002/submissions/f6eee4b0-4f58-4f8f-8af9-82d02ab32490\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    L = 0\n    \n    for i in range(n):\n        qc.h(i)\n        \n    \n    qc.compose(o, inplace=True)\n    \n    L = 0\n    \n    for i in range(n):\n        qc.h(i)\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(PhaseGate(math.pi), [0])\n    else:\n        qc.append(PhaseGate(math.pi).control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n            \n    for i in range(n):\n        qc.h(i)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A10932C10FF39", "submission_order": 1, "result": "WA", "execution_time": "1196 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    # 各量子ビットに対して角度T_iに基づく状態を作成\n    for i in range(n):\n        qc.ry(2 * T[i], i)  # 各ビットにRYゲートで角度を設定\n\n    # 2 |ψ⟩⟨ψ| - I の拡散演算子の実装\n    qc.h(range(n))  # すべてのビットにHadamardゲートを適用\n    qc.x(range(n))  # すべてのビットにXゲートを適用\n\n    # マルチ制御Zゲートを適用\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)  # 最後のビットに対して制御Z\n    qc.h(n-1)\n\n    qc.x(range(n))  # 再びXゲートを適用\n    qc.h(range(n))  # 再びHadamardゲートを適用\n\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A1135D69391AE", "submission_order": 1, "result": "RE", "execution_time": "1610 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n\n    qc1 = QuantumCircuit(1)\n    qc1.z(0)\n    custom = qc1.to_gate().control(n-1)\n\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A1135D69391AE", "submission_order": 2, "result": "WA", "execution_time": "1290 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, HGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n\n    qc1 = QuantumCircuit(1)\n    qc1.z(0)\n    custom = qc1.to_gate().control(n-1)\n\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A1135D69391AE", "submission_order": 3, "result": "WA", "execution_time": "1442 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, HGate\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n    for i in range(n):\n        qc.x(i)\n\n    qc1 = QuantumCircuit(1)\n    qc1.z(0)\n    custom = qc1.to_gate().control(n-1)\n\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A1135D69391AE", "submission_order": 4, "result": "WA", "execution_time": "1231 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, HGate\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n    for i in range(n):\n        qc.x(i)\n\n    qc1 = QuantumCircuit(1)\n    qc1.z(0)\n    custom = qc1.to_gate().control(n-1)\n\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.ry(-T[i]*2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A1135D69391AE", "submission_order": 5, "result": "AC", "execution_time": "1638 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, HGate\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    abc = [0] * n\n    for i in range(n):\n        abc[i]=i\n    for i in range(n):\n        qc.ry(-T[i]*2,i)\n    for i in range(n):\n        qc.x(i)\n\n    qc1 = QuantumCircuit(1)\n    qc1.z(0)\n    custom = qc1.to_gate().control(n-1)\n\n    qc.ry(np.pi*2,n-1)\n    qc.append(custom, abc)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.ry(T[i]*2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A19F17B013114", "submission_order": 1, "result": "AC", "execution_time": "2111 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt\nfrom qiskit.circuit.library import ZGate\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve1(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    \n    qc.append(ZGate().control(n-1), range(n))\n    \n    for i in range(n):\n        qc.x(i)\n \n    return qc\n\ndef solve2(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    qc.compose(solve1(n), inplace=True)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n    \n    qc.compose(solve1(n), inplace=True)\n    \n    for i in range(n):\n        qc.ry(2 * T[i], i)\n \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A1A390C93A13D", "submission_order": 1, "result": "WA", "execution_time": "1848 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef psi(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(psi(n, T), inplace=True)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    qc.compose(psi(n, T).inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A1A390C93A13D", "submission_order": 2, "result": "AC", "execution_time": "2092 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\n\ndef psi(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(psi(n, T).inverse(), inplace=True)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n    qc.compose(psi(n, T), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A4497F8EF670D", "submission_order": 1, "result": "RE", "execution_time": "1234 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef reflect(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n \n    return qc\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.h(range(n))\n    qc.compose(reflect(n), inplace=True)\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A4497F8EF670D", "submission_order": 2, "result": "AC", "execution_time": "1749 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n \n \ndef reflect(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n \n    return qc\n \n \ndef rotate(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n \n    return qc\n \n \ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.compose(rotate(n, T).inverse(), inplace=True)\n    qc.compose(reflect(n), inplace=True)\n    qc.compose(rotate(n, T), inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A67E5CBA455A9", "submission_order": 1, "result": "AC", "execution_time": "1621 ms", "memory": "156 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    # asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef preparation(targets: list[int], thetas: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(len(targets))\n    for i in range(len(targets)):\n        qc.ry(thetas[i] * 2, targets[i])\n    return qc\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    targets = list(range(n))\n    o = preparation(targets, T)\n\n    qc.compose(o.inverse(), inplace=True)\n    qc.x(targets)\n    qc.mcp(pi, targets[:-1], targets[-1])\n    qc.x(targets)\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A6A1D6B7E7628", "submission_order": 1, "result": "WA", "execution_time": "1929 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Step 1: Prepare the state |psi>\n    for i in range(n):\n        theta = T[i]\n        # Apply Ry rotation to prepare the state |psi>\n        qc.ry(2 * theta, i)  # R_y(2 * theta) prepares cos(theta)|0> + sin(theta)|1>\n    \n    # Step 2: Apply the reflection operation\n    # We need to apply a controlled operation that reflects across |psi>\n    # This can be done by applying a series of gates that create the reflection\n    # We will use the fact that |psi> is already prepared in the circuit\n    \n    # To reflect across |psi>, we can use the following:\n    # 1. Apply a Hadamard to all qubits\n    qc.h(range(n))\n    \n    # 2. Apply the controlled rotation to flip the state\n    for i in range(n):\n        qc.ry(-2 * T[i], i)  # This is the inverse operation to reflect\n    \n    # 3. Apply Hadamard again to all qubits\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A770C659E8684", "submission_order": 1, "result": "WA", "execution_time": "1673 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n#https://www.qcoder.jp/ja/contests/QPC002/submissions/f6eee4b0-4f58-4f8f-8af9-82d02ab32490\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    L = 0\n    \n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(ZGate(), [0])\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n            \n    for i in range(n):\n        qc.ry((-2) * T[i], i)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A770C659E8684", "submission_order": 2, "result": "AC", "execution_time": "1731 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n#https://www.qcoder.jp/ja/contests/QPC002/submissions/f6eee4b0-4f58-4f8f-8af9-82d02ab32490\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    L = 0\n    \n    for i in range(n):\n        qc.ry((-2) * T[i], i)\n\n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n        \n    if n == 1:\n        qc.append(ZGate(), [0])\n    else:\n        qc.append(ZGate().control(n - 1), range(n))\n    \n    for i in range(n):\n        if not (L >> i) & 1:\n            qc.x(i)\n            \n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A843DA6457DA4", "submission_order": 1, "result": "AC", "execution_time": "1884 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    U = QuantumCircuit(n)\n    for i in range(n):\n        U.ry(2 * T[i], i)\n    qc.compose(U.inverse(), inplace=True)\n\n    for i in range(n):\n        qc.x(i)\n    qc.h(n - 1)\n    if n == 2:\n        qc.cx(0, 1)\n    else:\n        qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n    for i in range(n):\n        qc.x(i)\n\n    qc.compose(U, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A929B2C696252", "submission_order": 1, "result": "RE", "execution_time": "1157 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    qc.rz(2*np.pi, n-1)\n    qc.x(list(range(n)))\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    qc.x(list(range(n)))\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A929B2C696252", "submission_order": 2, "result": "WA", "execution_time": "1278 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    qc.rz(2*np.pi, n-1)\n    qc.x(list(range(n)))\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    qc.x(list(range(n)))\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A929B2C696252", "submission_order": 3, "result": "WA", "execution_time": "1205 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    qc.rz(2*np.pi, n-1)\n    qc.x(list(range(n)))\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    qc.x(list(range(n)))\n    for i in range(n):\n        qc.ry(T[i] * -2, i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A929B2C696252", "submission_order": 4, "result": "AC", "execution_time": "1618 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(T[i] * -2, i)\n    qc.rz(2*np.pi, n-1)\n    qc.x(list(range(n)))\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    qc.x(list(range(n)))\n    for i in range(n):\n        qc.ry(T[i] * 2, i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A9628595285E3", "submission_order": 1, "result": "WA", "execution_time": "1201 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef zero_to_psi(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for idx in range(0, n):\n        qc.ry(2*T[idx], idx)\n\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(zero_to_psi(n, T).inverse(), inplace=True)\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.h(range(n))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    qc.compose(zero_to_psi(n, T), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A9628595285E3", "submission_order": 2, "result": "WA", "execution_time": "1198 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef zero_to_psi(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for idx in range(0, n):\n        qc.ry(2*T[idx], idx)\n\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(zero_to_psi(n, T), inplace=True)\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.h(range(n))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    qc.compose(zero_to_psi(n, T).inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A9628595285E3", "submission_order": 3, "result": "WA", "execution_time": "1214 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef zero_to_psi(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for idx in range(0, n):\n        qc.ry(2*T[idx], idx)\n\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(zero_to_psi(n, T), inplace=True)\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    qc.compose(zero_to_psi(n, T).inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A9628595285E3", "submission_order": 4, "result": "AC", "execution_time": "1669 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef zero_to_psi(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for idx in range(0, n):\n        qc.ry(2*T[idx], idx)\n\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(zero_to_psi(n, T).inverse(), inplace=True)\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    qc.compose(zero_to_psi(n, T), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A962F1662ADCD", "submission_order": 1, "result": "AC", "execution_time": "1824 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi, acos\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qubits = list(range(n))\n\n    for i, t in enumerate(T):\n        qc.ry(-2 * t, i)\n\n    qc.x(qubits)\n    qc.mcp(pi, qubits[1:], 0)\n    qc.x(qubits)\n\n    for i, t in enumerate(T):\n        qc.ry(2 * t, i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A98323A107013", "submission_order": 1, "result": "WA", "execution_time": "1735 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n\ndef b5(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    b5(qc)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A98323A107013", "submission_order": 2, "result": "WA", "execution_time": "1461 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    b4(qc)\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A98323A107013", "submission_order": 3, "result": "AC", "execution_time": "2066 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\ndef rotate(n: int, T: list[float]) -> QuantumCircuit:\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    return qc\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(rotate(n, T).inverse(), inplace=True)\n    b4(qc)\n    qc.compose(rotate(n, T), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A984644E10AD1", "submission_order": 1, "result": "AC", "execution_time": "1682 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(len(T)):\n        qc.ry(-T[i]*2,i)\n\n    for i in range(n):\n        if not (1 << i) & 0:\n            qc.x(i)\n    \n    qc.mcp(math.pi, list(range(n - 1)), n - 1)\n \n    for i in range(n):\n        if not (1 << i) & 0:\n            qc.x(i)       \n\n    for i in range(len(T)):\n        qc.ry(T[i]*2,i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A9DA7CC648392", "submission_order": 1, "result": "RE", "execution_time": "1229 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n - 1)\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.x(i)\n        qc.ry(2 * T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A9DA7CC648392", "submission_order": 2, "result": "WA", "execution_time": "1472 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n - 1)\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.x(i)\n        qc.ry(2 * T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A9DA7CC648392", "submission_order": 3, "result": "WA", "execution_time": "1257 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n - 1)\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.x(i)\n        qc.ry(-2 * T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "A9DA7CC648392", "submission_order": 4, "result": "AC", "execution_time": "1844 ms", "memory": "155 MiB", "code": "'''python\nfrom math import pi\n\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCPhaseGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    mc_z_gate = MCPhaseGate(pi, num_ctrl_qubits=n - 1)\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n        qc.x(i)\n    qc.append(mc_z_gate, [i for i in range(n)])\n    for i in range(n):\n        qc.x(i)\n        qc.ry(2 * T[i], i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AA5A1E2D6A45B", "submission_order": 1, "result": "RE", "execution_time": "1230 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        qc.ry(2*t, qubit)\n        qc.x(qubit)\n\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    \n    for qubit,t in enumerate(T):\n        qc.ry(-2*t, qubit)\n        qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AA5A1E2D6A45B", "submission_order": 2, "result": "RE", "execution_time": "1195 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        qc.ry(2*t, qubit)\n        qc.x(qubit)\n\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    \n    for qubit,t in enumerate(T):\n        qc.ry(-2*t, qubit)\n        qc.x(qubit)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AA5A1E2D6A45B", "submission_order": 3, "result": "RE", "execution_time": "1254 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        qc.ry(2*t, qubit)\n        qc.x(qubit)\n\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    \n    for qubit,t in enumerate(T):\n        qc.x(qubit)\n        qc.ry(-2*t, qubit)\n        \n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AA5A1E2D6A45B", "submission_order": 4, "result": "WA", "execution_time": "1619 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        qc.ry(2*t, qubit)\n        qc.x(qubit)\n\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    \n    for qubit,t in enumerate(T):\n        qc.x(qubit)\n        qc.ry(-2*t, qubit)\n        \n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AA5A1E2D6A45B", "submission_order": 5, "result": "RE", "execution_time": "1184 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        qc.ry(-2*t, qubit)\n        \n        qc.x(qubit)\n\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    \n    for qubit,t in enumerate(T):\n        qc.x(qubit)\n        qc.ry(2*t, qubit)\n        \n        \n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AA5A1E2D6A45B", "submission_order": 6, "result": "AC", "execution_time": "1603 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit,t in enumerate(T):\n        qc.ry(-2*t, qubit)\n        \n        qc.x(qubit)\n\n    qc.mcp(np.pi, list(range(n-1)), n-1)\n    \n    for qubit,t in enumerate(T):\n        qc.x(qubit)\n        qc.ry(2*t, qubit)\n        \n        \n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AB075B96A63CC", "submission_order": 1, "result": "WA", "execution_time": "2159 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i],i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.ry(-2*T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AB075B96A63CC", "submission_order": 2, "result": "AC", "execution_time": "2294 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(-2*T[i],i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.ry(2*T[i],i)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AB7A915205F62", "submission_order": 1, "result": "AC", "execution_time": "1951 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    sub_qc = QuantumCircuit(n)\n    for i, t in enumerate(T):\n        sub_qc.ry(2 * t, i)\n\n    qc.compose(sub_qc.inverse(), inplace=True)\n\n    qc.x(range(n))\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n    qc.x(range(n))\n\n    qc.compose(sub_qc, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "ABF7204AD27A7", "submission_order": 1, "result": "AC", "execution_time": "1555 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef b3(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*T[i], i)\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init = [0]*(2**n)\n    # init[2] = 1\n    # qc.initialize(init)\n\n    # Write your code here:\n    qc.compose(b3(n, T).inverse(), inplace=True)\n\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    qc.append(GlobalPhaseGate(math.pi))\n\n    qc.compose(b3(n, T), inplace=True)\n\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3, [0]*3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC003_B7", "user": "ACA5A72B6BF6E", "submission_order": 1, "result": "WA", "execution_time": "1201 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nfrom math import pi\n\ndef solve(n: int, T) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.ry(2 * T[i], i)\n\tqc.x(range(n))\n\tqc.h(n - 1)\n\tqc.mcx(list(range(n - 1)), n - 1)\n\tqc.h(n - 1)\n\tqc.x(range(n))\n\tfor i in range(n):\n\t\tqc.ry(-2 * T[i], i)\n\treturn qc\n'''"}
{"problem": "QPC003_B7", "user": "ACA5A72B6BF6E", "submission_order": 2, "result": "WA", "execution_time": "1483 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nfrom math import pi\n\ndef solve(n: int, T) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.ry(2 * T[i], i)\n\tqc.x(range(n))\n\tqc.h(n - 1)\n\tqc.mcx(list(range(n - 1)), n - 1)\n\tqc.h(n - 1)\n\tqc.x(range(n))\n\tfor i in range(n):\n\t\tqc.ry(2 * T[i], i)\n\treturn qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 1, "result": "WA", "execution_time": "1237 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        # Aplicar una rotación Ry de 2*T[i] al qubit i\n        qc.ry(2 * T[i], i)\n        # Aplicar la compuerta Z al qubit i\n        qc.z(i)\n        # Aplicar una rotación Ry de -2*T[i] al qubit i\n        qc.ry(-2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 2, "result": "RE", "execution_time": "1290 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Paso 1: Preparar el estado |ψ⟩ aplicando RY(2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    \n    # Paso 2: Implementar la reflexión 2|0⟩⟨0|^{⊗n} - I\n    # Aplicar Hadamard al último qubit\n    qc.h(n-1)\n    \n    # Aplicar puerta multi-controlada (MCX) con los primeros n-1 qubits como controles\n    controls = list(range(n-1))\n    target = n-1\n    if n == 2:\n        # Para n=2, no se necesitan ancillas\n        qc.ccx(controls[0], controls[1], target)\n    else:\n        # Para n > 2, usar la puerta MCX estándar que maneja ancillas internamente\n        qc.mcx(controls, target)\n    \n    # Aplicar nuevamente Hadamard al último qubit\n    qc.h(n-1)\n    \n    # Paso 3: Deshacer la preparación del estado |ψ⟩ aplicando RY(-2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 3, "result": "RE", "execution_time": "1477 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Paso 1: Preparar el estado |ψ⟩ aplicando RY(2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    \n    # Paso 2: Implementar la reflexión 2|0⟩⟨0|^{⊗n} - I\n    # Aplicar Hadamard al último qubit\n    qc.h(n-1)\n    \n    # Aplicar puerta multi-controlada (MCX) con los primeros n-1 qubits como controles\n    controls = list(range(n-1))\n    target = n-1\n    if n == 2:\n        # Para n=2, no se necesitan ancillas\n        qc.ccx(controls[0], controls[1], target)\n    else:\n        # Para n > 2, usar la puerta MCX estándar que maneja ancillas internamente\n        qc.mcx(controls, target)\n    \n    # Aplicar nuevamente Hadamard al último qubit\n    qc.h(n-1)\n    \n    # Paso 3: Deshacer la preparación del estado |ψ⟩ aplicando RY(-2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 4, "result": "WA", "execution_time": "1238 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Paso 1: Preparar el estado |ψ⟩ aplicando RY(2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    \n    # Paso 2: Implementar la reflexión 2|0⟩⟨0|^{⊗n} - I\n    # Esto se logra reflejando sobre |0⟩^{⊗n}:\n    # 1. Aplicar X a todos los qubits para convertir |0⟩^{⊗n} en |1⟩^{⊗n}\n    qc.x(range(n))\n    \n    if n == 2:\n        # Para n=2, usar una puerta CZ directamente\n        qc.cz(0, 1)\n    else:\n        # Para n > 2, implementar una reflexión multi-controlada\n        # Aplicar Hadamard al último qubit\n        qc.h(n-1)\n        \n        # Aplicar la puerta MCX con los primeros n-1 qubits como controles y el último como objetivo\n        qc.mcx(list(range(n-1)), n-1)\n        \n        # Aplicar nuevamente Hadamard al último qubit\n        qc.h(n-1)\n    \n    # 2. Aplicar X a todos los qubits para revertir la inversión\n    qc.x(range(n))\n    \n    # Paso 3: Deshacer la preparación del estado |ψ⟩ aplicando RY(-2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 5, "result": "WA", "execution_time": "1568 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Paso 1: Preparar el estado |psi> aplicando RY(2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    \n    # Paso 2: Implementar la reflexión 2|psi><psi| - I\n    # Esto se logra reflejando sobre |0>^{⊗n}:\n    # 1. Aplicar X a todos los qubits para convertir |0>^{⊗n} en |1>^{⊗n}\n    qc.x(range(n))\n    \n    # 2. Aplicar la reflexión sobre |1>^{⊗n}\n    if n == 1:\n        qc.z(0)\n    elif n == 2:\n        qc.cz(0, 1)\n    else:\n        # Para n > 2, implementar una puerta multi-controlada Z\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    \n    # 3. Aplicar X a todos los qubits para revertir la inversión\n    qc.x(range(n))\n    \n    # Paso 3: Deshacer la preparación del estado |psi> aplicando RY(-2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 6, "result": "WA", "execution_time": "1269 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Paso 1: Preparar el estado |ψ⟩ aplicando RY(2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n    \n    # Paso 2: Implementar la reflexión 2|0⟩⟨0|^{⊗n} - I\n    # 2.1 Aplicar X a todos los qubits para convertir |0⟩^{⊗n} en |1⟩^{⊗n}\n    qc.x(range(n))\n    \n    # 2.2 Aplicar una puerta multi-controlada Z\n    if n == 1:\n        qc.z(0)\n    elif n == 2:\n        qc.cz(0, 1)\n    else:\n        # Para n > 2, implementar una puerta multi-controlada Z usando puertas Hadamard y MCX\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    \n    # 2.3 Aplicar X a todos los qubits para revertir la inversión\n    qc.x(range(n))\n    \n    # 2.4 Aplicar una fase global de -1 para corregir la inversión en el estado |0⟩^{⊗n}\n    qc.z(range(n))\n    \n    # Paso 3: Deshacer la preparación del estado |ψ⟩ aplicando RY(-2T_i) a cada qubit\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 7, "result": "WA", "execution_time": "1241 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Definir el subcircuito que prepara el estado |\\psi⟩\n    def prepare_psi():\n        sub_qc = QuantumCircuit(n)\n        for i in range(n):\n            sub_qc.ry(2 * T[i], i)\n        return sub_qc\n\n    # Paso 1: Aplicar U para preparar |\\psi⟩\n    U = prepare_psi()\n    qc.compose(U, inplace=True)\n\n    # Paso 2: Implementar la reflexión sobre |0⟩^{⊗n}\n    qc.x(range(n))\n    if n == 1:\n        qc.z(0)\n    elif n == 2:\n        qc.cz(0, 1)\n    else:\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    qc.x(range(n))\n\n    # Paso 3: Aplicar U† para deshacer la preparación de |\\psi⟩\n    qc.compose(U.inverse(), inplace=True)  # Usando el hint proporcionado\n\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 8, "result": "WA", "execution_time": "1222 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Definir el subcircuito que prepara el estado |\\psi⟩\n    def prepare_psi():\n        sub_qc = QuantumCircuit(n)\n        for i in range(n):\n            sub_qc.ry(2 * T[i], i)\n        return sub_qc\n\n    # Paso 1: Aplicar U para preparar |\\psi⟩\n    U = prepare_psi()\n    #qc.compose(U, inplace=True)\n\n    # Paso 2: Implementar la reflexión sobre |0⟩^{⊗n}\n    qc.x(range(n))\n    if n == 1:\n        qc.z(0)\n    elif n == 2:\n        qc.cz(0, 1)\n    else:\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n    qc.x(range(n))\n\n    # Paso 3: Aplicar U† para deshacer la preparación de |\\psi⟩\n    qc.compose(U.inverse(), inplace=True)  # Usando el hint proporcionado\n\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 9, "result": "WA", "execution_time": "1296 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Define the subcircuit that prepares |\\psi⟩\n    def prepare_psi():\n        sub_qc = QuantumCircuit(n)\n        for i in range(n):\n            sub_qc.ry(2 * T[i], i)\n        return sub_qc\n\n    # Step 1: Apply U† to unprepare |\\psi⟩\n    qc.compose(prepare_psi().inverse(), inplace=True)\n\n    # Step 2: Implement the reflection R = 2|0^n⟩⟨0^n| - I\n    if n == 1:\n        qc.z(0)\n    elif n == 2:\n        qc.cz(0, 1)\n    else:\n        # Apply a multi-controlled Z gate without X gates\n        qc.h(n - 1)  # Apply Hadamard to the target qubit\n        qc.mcx(list(range(n - 1)), n - 1)  # Multi-controlled X gate\n        qc.h(n - 1)  # Apply Hadamard again to the target qubit\n\n    # Step 3: Apply U to prepare |\\psi⟩\n    qc.compose(prepare_psi(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 10, "result": "WA", "execution_time": "1711 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    def prepare_psi(n: int, T: list[float]) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.ry(2 * T[i], i)\n        return qc\n\n    # Paso 1: Preparar el estado |psi>\n    psi_circuit = prepare_psi(n, T)\n    qc.compose(psi_circuit, inplace=True)\n    \n    # Paso 2: Aplicar la operación de Grover\n    # Aplicar reflexión sobre el estado |0> -> Hadamard en todos los qubits\n    qc.h(range(n))\n    # Aplicar X en todos los qubits\n    qc.x(range(n))\n    # Aplicar la puerta de múltiples control Z (una Z en el último qubit con todos los demás como control)\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)  # mcx con n-1 controles\n    qc.h(n - 1)\n    # Aplicar X de nuevo\n    qc.x(range(n))\n    # Aplicar Hadamard de nuevo en todos los qubits\n    qc.h(range(n))\n    \n    # Paso 3: Aplicar la reflexión sobre el estado |psi>\n    qc.compose(psi_circuit.inverse(), inplace=True)\n    qc.compose(psi_circuit, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    def prepare_psi(n: int, T: list[float]) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.ry(2 * T[i], i)\n        return qc\n\n    # Paso 1: Preparar el estado |psi>\n    psi_circuit = prepare_psi(n, T)\n    qc.compose(psi_circuit, inplace=True)\n    \n    # Paso 2: Aplicar la operación de Grover\n    # Aplicar reflexión sobre el estado |0> -> Hadamard en todos los qubits\n    qc.h(range(n))\n    # Aplicar X en todos los qubits\n    qc.x(range(n))\n    # Aplicar la puerta de múltiples control Z (una Z en el último qubit con todos los demás como control)\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)  # mcx con n-1 controles\n    qc.h(n - 1)\n    # Aplicar X de nuevo\n    qc.x(range(n))\n    # Aplicar Hadamard de nuevo en todos los qubits\n    qc.h(range(n))\n    \n    # Paso 3: Aplicar la reflexión sobre el estado |psi>\n    qc.compose(psi_circuit.inverse(), inplace=True)\n    \"qc.compose(psi_circuit, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 12, "result": "WA", "execution_time": "1183 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    def prepare_psi(n: int, T: list[float]) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n        for i in range(n):\n            qc.ry(2 * T[i], i)\n        return qc\n\n    # Paso 1: Preparar el estado |psi>\n    psi_circuit = prepare_psi(n, T)\n    qc.compose(psi_circuit, inplace=True)\n    \n    # Paso 2: Aplicar la operación de Grover\n    # Aplicar reflexión sobre el estado |0> -> Hadamard en todos los qubits\n    qc.h(range(n))\n    # Aplicar X en todos los qubits\n    qc.x(range(n))\n    # Aplicar la puerta de múltiples control Z (una Z en el último qubit con todos los demás como control)\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)  # mcx con n-1 controles\n    qc.h(n - 1)\n    # Aplicar X de nuevo\n    qc.x(range(n))\n    # Aplicar Hadamard de nuevo en todos los qubits\n    qc.h(range(n))\n    \n    # Paso 3: Aplicar la reflexión sobre el estado |psi>\n    qc.compose(psi_circuit.inverse(), inplace=True)\n    #qc.compose(psi_circuit, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD441B22F4A84", "submission_order": 13, "result": "WA", "execution_time": "1186 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Paso 1: Definir el circuito U que prepara |psi>\n    U = QuantumCircuit(n)\n    for i in range(n):\n        U.ry(2 * T[i], i)\n    \n    # Aplicar U al circuito principal\n    qc.compose(U, inplace=True)\n    \n    # Paso 2: Aplicar la reflexión 2|0><0| - I\n    # Aplicar X a todos los qubits\n    qc.x(range(n))\n    \n    # Aplicar una puerta Z controlada multi-qubit\n    # Implementamos una puerta Z multi-controlada utilizando una puerta MCX con Hadamard\n    qc.h(n-1)  # Aplicar Hadamard al último qubit\n    qc.mcx(list(range(n-1)), n-1)  # Puerta MCX con los primeros n-1 qubits como controles\n    qc.h(n-1)  # Aplicar Hadamard nuevamente al último qubit\n    \n    # Aplicar X nuevamente a todos los qubits\n    qc.x(range(n))\n    \n    # Paso 3: Aplicar U† (inversa de U)\n    qc.compose(U.inverse(), inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AD5950CB1D2B5", "submission_order": 1, "result": "AC", "execution_time": "2937 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef zero_to_psi(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for idx in range(0, n):\n        qc.ry(2*T[idx], idx)\n\n    return qc\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(zero_to_psi(n, T).inverse(), inplace=True)\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    qc.compose(zero_to_psi(n, T), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AE9ED74C983F6", "submission_order": 1, "result": "WA", "execution_time": "1206 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Ry gateによる位相変換を実行\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    #数学的な確証はないがこうすればうまくいくはず\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n    \n\n    #これは確定でいるので書いておく\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n\n    #再度反転！確証はない！\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AE9ED74C983F6", "submission_order": 2, "result": "WA", "execution_time": "1183 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Ry gateによる位相変換を実行\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    #数学的な確証はないがこうすればうまくいくはず\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n    \n\n    #これは確定でいるので書いておく\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n\n    #再度反転！確証はない！\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AE9ED74C983F6", "submission_order": 3, "result": "WA", "execution_time": "1270 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    #Ry gateによる位相変換を実行\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    #数学的な確証はないがこうすればうまくいくはず\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n    \n\n    #これは確定でいるので書いておく\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1)\n    qc.h(n - 1)\n\n    #再度反転！確証はない！\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B7", "user": "AE9ED74C983F6", "submission_order": 4, "result": "WA", "execution_time": "1227 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\nimport math\n\ndef solve(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    for i in range(n):\n        qc.ry(-2 * T[i], i)\n\n    qc.h(n - 1)\n    qc.mcx(list(range(n - 1)), n - 1) \n    qc.h(n - 1)\n\n    for i in range(n):\n        qc.ry(2 * T[i], i)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 1, "result": "RE", "execution_time": "1731 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    k = 5\n    for i in range(n):\n        qc.h(i)\n    for _ in range(k):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 2, "result": "RE", "execution_time": "1736 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    k = 5\n    for i in range(n):\n        qc.h(i)\n    for _ in range(k):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 3, "result": "RE", "execution_time": "1826 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n))\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 4, "result": "WA", "execution_time": "2013 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n+1))\n    qc.z(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    k = 5\n    for _ in range(k);\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    k = 5\n    for j in range(k);\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 7, "result": "WA", "execution_time": "1968 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n+1))\n    qc.z(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n+1))\n    qc.z(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n+1))\n    qc.z(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n+1))\n    qc.z(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n+1))\n    qc.z(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    qc.append(o,qargs = range(n+1))\n    qc.z(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1),qargs = range(n))\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 8, "result": "WA", "execution_time": "1893 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    for _ in range(5):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 9, "result": "WA", "execution_time": "2048 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    for _ in range(10):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 10, "result": "DLE", "execution_time": "1838 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    for _ in range(45):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 11, "result": "WA", "execution_time": "2070 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    for _ in range(35):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 12, "result": "WA", "execution_time": "1950 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    for _ in range(10):\n        qc.x(n)\n        qc.h(n)\n        qc.append(o,qargs = range(n+1))\n        qc.h(n)\n        qc.x(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 13, "result": "WA", "execution_time": "1964 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    for _ in range(15):\n        qc.x(n)\n        qc.h(n)\n        qc.append(o,qargs = range(n+1))\n        qc.h(n)\n        qc.x(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 14, "result": "WA", "execution_time": "2034 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    for _ in range(25):\n        qc.x(n)\n        qc.h(n)\n        qc.append(o,qargs = range(n+1))\n        qc.h(n)\n        qc.x(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 15, "result": "WA", "execution_time": "1922 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    k = int(math.pi*n**0.5/4)\n    for _ in range(k):\n        qc.x(n)\n        qc.h(n)\n        qc.append(o,qargs = range(n+1))\n        qc.h(n)\n        qc.x(n)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 16, "result": "WA", "execution_time": "1946 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    k = int((math.pi*n**0.5)/4)\n    for _ in range(k):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        qc.append(o,qargs = range(n+1))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 17, "result": "DLE", "execution_time": "1930 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    k = 45\n    for _ in range(k):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        qc.append(o,qargs = range(n+1))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 18, "result": "WA", "execution_time": "2113 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    k = 30\n    for _ in range(k):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        qc.append(o,qargs = range(n+1))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 19, "result": "WA", "execution_time": "2001 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(n**(-0.5)))**2 for r in range(30)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        qc.append(o,qargs = range(n+1))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A067F155B41BA", "submission_order": 20, "result": "AC", "execution_time": "2161 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(30)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        qc.append(o,qargs = range(n+1))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A08D6DA73194C", "submission_order": 1, "result": "DLE", "execution_time": "3411 ms", "memory": "166 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef flipzero(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        if i == 0:\n            qc.z(0)\n        else:\n            qc.append(ZGate().control(i), range(i+1))\n        qc.x(i)\n    \n    for i in range(n):\n        qc.x(i)\n \n    return qc\n\ndef Us(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    qc.compose(flipzero(n), inplace=True)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n\ndef solve(n: int, Uf: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.x(n)\n    qc.h(n)\n    for i in range(n):\n        qc.h(i)\n\n    r = pi / 4 * sqrt(2 ** n)\n    num = int(round(r))\n    if n == 2:\n        num = 1\n\n    for _ in range(num):\n        qc.compose(Uf, inplace=True)\n        qc.compose(Us(n), inplace=True)\n    \n    qc.h(n)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A08D6DA73194C", "submission_order": 2, "result": "AC", "execution_time": "2695 ms", "memory": "179 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef flipzero(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.x(i)\n\n    qc.append(ZGate().control(n-1), range(n))\n    \n    for i in range(n):\n        qc.x(i)\n \n    return qc\n\ndef Us(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    \n    qc.compose(flipzero(n), inplace=True)\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n\ndef solve(n: int, Uf: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    qc.x(n)\n    qc.h(n)\n    for i in range(n):\n        qc.h(i)\n\n    r = pi / 4 * sqrt(2 ** n)\n    num = int(round(r))\n    if n == 2:\n        num = 1\n\n    for _ in range(num):\n        qc.compose(Uf, inplace=True)\n        qc.compose(Us(n), inplace=True)\n    \n    qc.h(n)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0D2CF31270A8", "submission_order": 1, "result": "WA", "execution_time": "1594 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Initialize ancilla qubit y to |-> state for phase-flip conversion\n    qc.x(y[0])\n    qc.h(y[0])\n    \n    # Step 2: Create initial superposition on x register\n    qc.h(x)\n    \n    # Step 3: Calculate optimal number of iterations\n    # For single target: M=1, N=2^n\n    # optimal_iterations ≈ π/4 * sqrt(N)\n    N = 2**n\n    optimal_iterations = round(math.pi / 4 * math.sqrt(N))\n    \n    # Step 4: Apply Grover operator optimal_iterations times\n    for _ in range(optimal_iterations):\n        # Phase-flip oracle: apply the given bit-flip oracle\n        # Since y is in |-> state, bit-flip becomes phase-flip\n        qc.compose(o, inplace=True)\n        \n        # Diffusion operator (amplitude amplification about average)\n        # 1. Apply H to all x qubits\n        qc.h(x)\n        \n        # 2. Apply X to all x qubits (to flip |0...0> to |1...1>)\n        qc.x(x)\n        \n        # 3. Apply multi-controlled Z gate (phase flip |1...1> state)\n        if n == 1:\n            qc.z(x[0])\n        elif n == 2:\n            qc.cz(x[0], x[1])\n        else:\n            # Multi-controlled Z gate using ancilla\n            # For n>2, we need to implement multi-controlled Z\n            # Using the fact that MCZ = MCX with target in |-> state\n            qc.h(x[n-1])  # Convert last qubit to |+/-⟩ basis\n            \n            # Multi-controlled X gate on last qubit\n            if n == 3:\n                qc.ccx(x[0], x[1], x[n-1])\n            else:\n                # For larger n, implement using decomposition\n                # This is a simplified approach for the contest\n                controls = list(range(n-1))\n                qc.mcx(controls, x[n-1])\n            \n            qc.h(x[n-1])  # Convert back\n        \n        # 4. Apply X to all x qubits (flip back)\n        qc.x(x)\n        \n        # 5. Apply H to all x qubits\n        qc.h(x)\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0D2CF31270A8", "submission_order": 2, "result": "WA", "execution_time": "1582 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Initialize uniform superposition on x qubits\n    for i in range(n):\n        qc.h(x[i])\n    \n    # Step 2: Initialize ancilla qubit y in |1> state for phase oracle\n    qc.x(y[0])\n    qc.h(y[0])\n    \n    # Step 3: Calculate optimal number of iterations\n    # For 1 marked state out of 2^n states: approximately π√(2^n)/4\n    num_iterations = int(np.pi * np.sqrt(2**n) / 4)\n    if num_iterations == 0:\n        num_iterations = 1\n    \n    # Step 4: Grover iterations\n    for _ in range(num_iterations):\n        # Apply oracle O\n        qc.compose(o, inplace=True)\n        \n        # Apply diffusion operator (inversion about average)\n        # H gates\n        for i in range(n):\n            qc.h(x[i])\n        \n        # X gates (flip all qubits)\n        for i in range(n):\n            qc.x(x[i])\n        \n        # Multi-controlled Z gate (phase flip on |111...1>)\n        if n == 1:\n            qc.z(x[0])\n        elif n == 2:\n            qc.cz(x[0], x[1])\n        else:\n            # Multi-controlled Z using ancilla-free implementation\n            qc.h(x[n-1])\n            for i in range(n-1):\n                qc.cx(x[i], x[n-1])\n            qc.h(x[n-1])\n        \n        # X gates (flip back)\n        for i in range(n):\n            qc.x(x[i])\n        \n        # H gates\n        for i in range(n):\n            qc.h(x[i])\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 1, "result": "RE", "execution_time": "1480 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(0.8 * n)):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 2, "result": "WA", "execution_time": "1265 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(0.8 * n)):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 3, "result": "RE", "execution_time": "1174 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\niter = [4, 4, 11, 9, 2, 2, 11, 7, 7]\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(iter[n - 2]))\n    for i in range(int(0.8 * n)):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 4, "result": "WA", "execution_time": "1376 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\niter = [4, 4, 11, 9, 2, 2, 11, 7, 7]\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(iter[n - 2]):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 5, "result": "WA", "execution_time": "1381 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\niter = [10, 4, 8, 2, 2, 2, 11, 7, 7]\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(iter[n - 2]):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 6, "result": "WA", "execution_time": "1294 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(3.14 / 4 * 3 * n)):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 7, "result": "WA", "execution_time": "1633 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(3.14 / 4 * 5 * n)):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 8, "result": "WA", "execution_time": "1211 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(3.14 / 4 * 4 * n)):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 9, "result": "WA", "execution_time": "1648 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    iter = 1\n    for i in range(20):\n        s = (iter + 1)* 2 * math.asin(1 / math.sqrt(n))\n        for j in range(6):\n            if abs(s - (j + 1 / 2) * math.pi) < 0.1: break\n        iter += 1\n    qc.h(range(n))\n    for i in range(iter):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 10, "result": "WA", "execution_time": "1733 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(0.8 * (2 ** n))):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A0E2E729A0246", "submission_order": 11, "result": "AC", "execution_time": "1835 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(range(n))\n    for i in range(int(0.8 * np.sqrt(2 ** n))):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(list(range(n)))\n        qc.mcp(np.pi, list(range(n-1)), n-1)\n        qc.x(list(range(n)))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A1239C0FA9524", "submission_order": 1, "result": "RE", "execution_time": "1381 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.h(range(n))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n    qc.compose(o, inplace=True)\n    qc.compose(refl(n), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A1239C0FA9524", "submission_order": 2, "result": "AC", "execution_time": "2717 ms", "memory": "173 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.h(range(n))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.h(x)\n\n    init_prob = math.sqrt(1/(2**n))\n    init_angle = math.acos(init_prob)\n    target_prob = 0.9\n    repeat = 0\n\n    while True:\n        angle = (2*repeat+1) * init_angle\n        curr_prob = math.cos(angle)**2\n        if curr_prob > target_prob:\n            break\n\n        qc.compose(o, inplace=True)\n        qc.compose(refl(n), inplace=True)\n    \n        repeat += 1\n\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A2313C782B8A8", "submission_order": 1, "result": "RE", "execution_time": "1425 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffuser(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    niter = math.floor(math.pi/4  * math.sqrt(2**n))\n    diff = diffuser(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(niter):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.compose(diff, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A2313C782B8A8", "submission_order": 2, "result": "DLE", "execution_time": "1622 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffuser(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    niter = math.floor(math.pi/4  * math.sqrt(2**n))\n    diff = diffuser(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(niter):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.compose(diff, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A2313C782B8A8", "submission_order": 3, "result": "WA", "execution_time": "1235 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffuser(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    niter = math.floor(math.pi/4  * math.sqrt(2**n))\n    diff = diffuser(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(niter):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.compose(diff, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A2313C782B8A8", "submission_order": 4, "result": "DLE", "execution_time": "1463 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffuser(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)\n    qc.h(n-1)\n\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    niter = math.floor(math.pi/4  * math.sqrt(2**n))\n    diff = diffuser(n)\n    for i in range(n):\n        qc.h(i)\n    for i in range(niter):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o, inplace=True)\n        qc.compose(diff, inplace=True)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A384B4CA7ED95", "submission_order": 1, "result": "WA", "execution_time": "1422 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A4908A0EDB229", "submission_order": 1, "result": "AC", "execution_time": "1744 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef b2(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.z(y[0])\n    qc.compose(o, inplace=True)\n    return qc\n\ndef b5(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # init = [0]*(2**n)\n    # init[2] = 1\n    # qc.initialize(init)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.h(0)\n    qc.mcx(list(range(1, n)), 0)\n    qc.h(0)\n    for i in range(n):\n        qc.x(i)\n    qc.append(GlobalPhaseGate(math.pi))\n    for i in range(n):\n        qc.h(i)\n    return qc\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    t = math.asin(1/math.sqrt(2**n))\n    for i in range(1, 100):\n        qc.compose(b2(n, o), inplace=True)\n        qc.compose(b5(n), list(range(n)), inplace=True)\n        if math.sin((2*i+1)*t)**2>=0.9:\n            break\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A500603F34821", "submission_order": 1, "result": "WA", "execution_time": "1613 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    for _ in range(int(math.pi / 4 * math.sqrt(2 ** n))):\n        qc.compose(o, inplace=True)\n        qc.z(n)\n        qc.compose(o, inplace=True)\n\n        qc.h(n - 1)\n        qc.mcx(list(range(n - 1)), n - 1)\n        qc.h(n - 1)\n        \n        qc.x(range(n))\n        qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A500603F34821", "submission_order": 2, "result": "WA", "execution_time": "1307 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    k = math.ceil(math.pi / 4 * math.sqrt(2 ** n))\n    for _ in range(k):\n        qc.compose(o, inplace=True)\n        qc.z(n)\n        qc.compose(o, inplace=True)\n\n        qc.h(n - 1)\n        qc.mcx(list(range(n - 1)), n - 1)\n        qc.h(n - 1)\n        \n        qc.x(range(n))\n        qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A59DC4B4C46AB", "submission_order": 1, "result": "WA", "execution_time": "1557 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    # 注意: 今回の与えられたオラクル O は，x が L であるときに y を反転させるので，\n    # y–レジスタを (|0⟩–|1⟩)/√2 にしておくと，O の作用は\n    #   |x⟩ (|0⟩–|1⟩)/√2 → { –|x⟩ (|0⟩–|1⟩)/√2   (x = L)\n    #                           |x⟩ (|0⟩–|1⟩)/√2    (x ≠ L) }\n    # となり，Grover オラクルとして利用できます．\n    #\n    # また，最終的に (x,y) = (L,L) を得るためには，x–レジスタが |L⟩ (ほぼ)になった後，\n    # little–エンディアンで x[0]（最下位ビット）の値に合わせて y を補正します．\n    #\n    # （なお，本問題では y–レジスタは 1 量子ビットであるため，\n    # 　最終的に |L⟩|L⟩ とできるのは L ∈ {0,1} であると解釈しています．）\n    \n    # x: n 量子ビット，y: 1 量子ビット\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(1, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # --- 1. 初期状態準備 ---\n    # x–レジスタを一様重ね合わせに\n    qc.h(x)\n    # y–レジスタを |0⟩ から (|0⟩–|1⟩)/√2 にする： X → H\n    qc.x(y)\n    qc.h(y)\n    \n    # --- 2. Grover 反復 ---\n    # 1 個の解があるとき，θ = arcsin(1/√(2^n))\n    theta = math.asin(1 / math.sqrt(2**n))\n    # 最適回数（四捨五入）:\n    r = int(round((math.pi / (4 * theta)) - 0.5))\n    \n    for _ in range(r):\n        # (a) オラクルの適用\n        qc.compose(o, qubits=x[:] + y[:], inplace=True)\n        # (b) 拡散演算子 (inversion–about–the–mean) を x–レジスタに作用\n        qc.h(x)\n        qc.x(x)\n        # ここで，|11…1⟩にのみ位相 –1 を付与する多重制御位相ゲートを MCPhaseGate で実装．\n        # x のうち，先頭 n–1 ビットを制御，最後のビットをターゲットとして働かせる．\n        qc.append(MCPhaseGate(math.pi, num_ctrl_qubits=n-1), \n                  qargs=list(x[:-1]) + [x[-1]])\n        qc.x(x)\n        qc.h(x)\n    \n    # --- 3. y–レジスタの補正 ---\n    # 現在，x–レジスタはほぼ |L⟩，y–レジスタは依然 (|0⟩–|1⟩)/√2 のままです．\n    # ここで，little–エンディアンでは x[0] が L の最下位ビットとなるので，\n    # その値に合わせて y を |L⟩ に変換します．\n    #\n    # 具体的には，\n    # ・まず y に H を作用すると (|0⟩–|1⟩)/√2 は |1⟩ になります．\n    qc.h(y)\n    # ・x[0] の値が 0 の場合にのみ y を反転させるように，x[0] を反転してから制御付き X を適用，\n    # 　その後，x[0] を元に戻します．\n    qc.x(x[0])\n    qc.cx(x[0], y[0])\n    qc.x(x[0])\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A59DC4B4C46AB", "submission_order": 2, "result": "WA", "execution_time": "1404 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    # x: n量子ビットレジスタ（little‐エンディアンで整数をエンコード）\n    # y: 1量子ビットレジスタ\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(1, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # 1. 初期状態の準備\n    qc.h(x)    # x‐レジスタを一様重ね合わせ状態に\n    qc.x(y)    # y を |0⟩→|1⟩に変換\n    qc.h(y)    # y を Hadamard して (|0⟩ - |1⟩)/√2 に\n    \n    # 2. Grover 反復回数の設定\n    theta = math.asin(1 / math.sqrt(2**n))\n    # r = round( (pi/(4θ)) - 0.5 ) 　と同値\n    r = int(round((math.pi / (4 * theta)) - 0.5))\n    \n    # 3. Grover 反復\n    for _ in range(r):\n        # (a) オラクル O の適用\n        qc.compose(o, inplace=True)  # 注意：ここは問題文の「qc.compose(o, inplace=True)」に従う\n        # (b) 拡散演算子（inversion-about-the-mean）を x‐レジスタに作用\n        qc.h(x)\n        qc.x(x)\n        qc.append(MCPhaseGate(math.pi, num_ctrl_qubits=n-1), qargs=list(x[:-1]) + [x[-1]])\n        qc.x(x)\n        qc.h(x)\n    \n    # 4. y‐レジスタの補正\n    # 現在、x‐レジスタはほぼ |L⟩、y‐レジスタは (|0⟩ - |1⟩)/√2 のまま．\n    # まず Hadamard で y を |1⟩に変換\n    qc.h(y)\n    # x[0]（LSB）が L の下位ビットと一致するはずなので、x[0] の値が 0 の場合にのみ y を反転する操作を実現するために\n    qc.x(x[0])\n    qc.cx(x[0], y[0])\n    qc.x(x[0])\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A60665E0C857A", "submission_order": 1, "result": "WA", "execution_time": "1759 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Prepare superposition on the n qubits\n    for i in range(n):\n        qc.h(x[i])  # Apply Hadamard gate to each qubit in the x register\n    \n    # Step 2: Apply the oracle\n    qc.compose(o, inplace=True)  # Apply the oracle O\n    \n    # Step 3: Measurement (not included in the circuit but will be done after)\n    # We will measure the x register to get the value of L\n    qc.measure_all()  # Measure all qubits\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A60665E0C857A", "submission_order": 2, "result": "WA", "execution_time": "2578 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import XGate\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    \n    # Apply Hadamard gate to all qubits\n    for i in range(n):\n        qc.h(x[i])\n    \n    # Apply the oracle circuit\n    qc.compose(o, inplace=True)\n    \n    # Apply Hadamard gate to all qubits again\n    for i in range(n):\n        qc.h(x[i])\n    \n    # Measure all qubits\n    qc.measure_all()\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A6B494456EB18", "submission_order": 1, "result": "AC", "execution_time": "3613 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.h(range(n))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.h(x)\n\n    init_prob = math.sqrt(1/(2**n))\n    init_angle = math.acos(init_prob)\n    target_prob = 0.9\n    repeat = 0\n\n    while True:\n        angle = (2*repeat+1) * init_angle\n        curr_prob = math.cos(angle)**2\n        if curr_prob > target_prob:\n            break\n\n        qc.compose(o, inplace=True)\n        qc.compose(refl(n), inplace=True)\n    \n        repeat += 1\n\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 1, "result": "RE", "execution_time": "1419 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.compose(o, inplace=True)\n    qc.p(math.pi,y)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(math.pi,list(range(n-1)),n-1)\n    for i in range(n):\n        qc.x(i)   \n    for i in range(n):\n        qc.h(i)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 2, "result": "RE", "execution_time": "1178 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h()\n    qc.compose(o, inplace=True)\n    qc.p(math.pi,y)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(math.pi,list(range(n-1)),n-1)\n    for i in range(n):\n        qc.x(i)   \n    for i in range(n):\n        qc.h(i)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 3, "result": "WA", "execution_time": "1295 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    qc.compose(o, inplace=True)\n    qc.p(math.pi,y)\n    qc.compose(o, inplace=True)\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.x(i)\n    qc.mcp(math.pi,list(range(n-1)),n-1)\n    for i in range(n):\n        qc.x(i)   \n    for i in range(n):\n        qc.h(i)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 4, "result": "WA", "execution_time": "1527 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(20):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        for i in range(n):\n            qc.x(i)   \n        for i in range(n):\n            qc.h(i)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 5, "result": "DLE", "execution_time": "1236 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(50):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        for i in range(n):\n            qc.x(i)   \n        for i in range(n):\n            qc.h(i)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 6, "result": "WA", "execution_time": "1686 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(30):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        for i in range(n):\n            qc.x(i)   \n        for i in range(n):\n            qc.h(i)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 7, "result": "WA", "execution_time": "1282 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(30):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        for i in range(n):\n            qc.x(i)   \n        for i in range(n):\n            qc.h(i)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 8, "result": "DLE", "execution_time": "1236 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(40):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        for i in range(n):\n            qc.x(i)   \n        for i in range(n):\n            qc.h(i)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 9, "result": "RE", "execution_time": "1160 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(40):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h()        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 10, "result": "DLE", "execution_time": "1336 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(40):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 11, "result": "DLE", "execution_time": "1336 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(35):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 12, "result": "DLE", "execution_time": "1181 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(34):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 13, "result": "DLE", "execution_time": "1182 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(33):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 14, "result": "DLE", "execution_time": "1175 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(32):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 15, "result": "WA", "execution_time": "1628 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    for j in range(31):\n        qc.compose(o, inplace=True)\n        qc.p(math.pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 16, "result": "RE", "execution_time": "1831 ms", "memory": "158 MiB", "code": "'''python\nfrom math import ceil,floor,acos,sqrt,pi\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    a=1 / sqrt(2**n)\n    r=round(pi/4/asin(a)-1/2)\n    for j in range(r):\n        qc.compose(o, inplace=True)\n        qc.p(pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(math.pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 17, "result": "RE", "execution_time": "1650 ms", "memory": "158 MiB", "code": "'''python\nfrom math import ceil,floor,acos,sqrt,pi\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    a=1 / sqrt(2**n)\n    r=round(pi/4/asin(a)-1/2)\n    for j in range(r):\n        qc.compose(o, inplace=True)\n        qc.p(pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A79EB4814D684", "submission_order": 18, "result": "AC", "execution_time": "2721 ms", "memory": "164 MiB", "code": "'''python\nfrom math import ceil,floor,asin,sqrt,pi\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.h(x)\n    a=1 / sqrt(2**n)\n    r=round(pi/4/asin(a)-1/2)\n    for j in range(r):\n        qc.compose(o, inplace=True)\n        qc.p(pi,y)\n        qc.compose(o, inplace=True)\n        qc.h(x)\n        qc.x(x)\n        qc.mcp(pi,list(range(n-1)),n-1)\n        qc.x(x)   \n        qc.h(x)        \n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A7FF16417352E", "submission_order": 1, "result": "WA", "execution_time": "1867 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        \n    \n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n    qc.z(y[0])\n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n    \n    for t in range(10):\n    \n        for i in range(n):\n            qc.h(i)\n\n        for i in range(n):\n            qc.x(i)\n        \n        if n == 1:\n            qc.append(ZGate(), [0])\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    \n        for i in range(n):\n            qc.x(i)\n            \n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A7FF16417352E", "submission_order": 2, "result": "DLE", "execution_time": "2360 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        \n    \n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n    qc.z(y[0])\n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n    \n    for t in range(100):\n    \n        for i in range(n):\n            qc.h(i)\n\n        for i in range(n):\n            qc.x(i)\n        \n        if n == 1:\n            qc.append(ZGate(), [0])\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    \n        for i in range(n):\n            qc.x(i)\n            \n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A7FF16417352E", "submission_order": 3, "result": "WA", "execution_time": "1452 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n        \n    \n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n    qc.z(y[0])\n    qc.compose(o, qubits=[*x, y[0]], inplace=True)\n    \n    for t in range(40):\n    \n        for i in range(n):\n            qc.h(i)\n\n        for i in range(n):\n            qc.x(i)\n        \n        if n == 1:\n            qc.append(ZGate(), [0])\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    \n        for i in range(n):\n            qc.x(i)\n            \n        for i in range(n):\n            qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A7FF16417352E", "submission_order": 4, "result": "DLE", "execution_time": "1766 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n    \n    \n    T = 40\n    for t in range(T):\n        qc.compose(o, qubits=[*x, y[0]], inplace=True)\n        qc.z(y[0])\n        qc.compose(o, qubits=[*x, y[0]], inplace=True)\n\n        for i in range(n):\n            qc.h(i)\n            \n        for i in range(n):\n            qc.x(i)\n        \n        if n == 1:\n            qc.append(ZGate(), [0])\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    \n        for i in range(n):\n            qc.x(i)\n            \n        for i in range(n):\n            qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A7FF16417352E", "submission_order": 5, "result": "WA", "execution_time": "1544 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n    \n    \n    T = 30\n    for t in range(T):\n        qc.compose(o, qubits=[*x, y[0]], inplace=True)\n        qc.z(y[0])\n        qc.compose(o, qubits=[*x, y[0]], inplace=True)\n\n        for i in range(n):\n            qc.h(i)\n            \n        for i in range(n):\n            qc.x(i)\n        \n        if n == 1:\n            qc.append(ZGate(), [0])\n        else:\n            qc.append(ZGate().control(n - 1), range(n))\n    \n        for i in range(n):\n            qc.x(i)\n            \n        for i in range(n):\n            qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A7FF16417352E", "submission_order": 6, "result": "WA", "execution_time": "1572 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n    \n    amp1 = -(2 ** (-n))\n    amp2 = 2 ** (-n)\n    \n    T = 1\n    for t in range(T):\n        qc.compose(o, qubits=[*x, y[0]], inplace=True)\n        qc.z(y[0])\n        qc.compose(o, qubits=[*x, y[0]], inplace=True)\n\n        for i in range(n):\n            qc.h(i)\n            \n        for i in range(n):\n            qc.x(i)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n    \n        for i in range(n):\n            qc.x(i)\n            \n        for i in range(n):\n            qc.h(i)\n        \n        amp1, amp2 = (math.sqrt(2 ** (-n)) - 1) * amp1 + (2 ** n - 1) * math.sqrt(2 ** (-n)) * amp2, math.sqrt(2 ** (-n)) * amp1 + (math.sqrt(2 ** (-n)) - 1) * amp2 + (2 ** n - 2) * math.sqrt(2 ** (-n)) * amp2\n        \n#        print(amp1)\n#        print(amp2)\n        \n        prob = amp1 * amp1 / (amp1 * amp1 + amp2 * amp2 * (2 ** n - 1))\n#        print(prob)\n        if prob > 0.92:\n            break\n                                  \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "A7FF16417352E", "submission_order": 7, "result": "WA", "execution_time": "1524 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.h(i)\n    \n    amp1 = -math.sqrt(2 ** (-n))\n    amp2 = math.sqrt(2 ** (-n))\n    \n    T = 30\n    for t in range(T):\n        qc.compose(o, qubits=[*x, y[0]], inplace=True)\n        qc.z(y[0])\n        qc.compose(o, qubits=[*x, y[0]], inplace=True)\n\n        for i in range(n):\n            qc.h(i)\n            \n        for i in range(n):\n            qc.x(i)\n        \n        qc.append(ZGate().control(n - 1), range(n))\n    \n        for i in range(n):\n            qc.x(i)\n            \n        for i in range(n):\n            qc.h(i)\n        \n        amp1, amp2 = (2 ** (-n) - 1) * amp1 + (2 ** n - 1) * 2 ** (-n) * amp2, math.sqrt(2 ** (-n)) * amp1 + (2 ** (-n) - 1) * amp2 + (2 ** n - 2) * math.sqrt(2 ** (-n)) * amp2\n        \n        prob = amp1 * amp1 / (amp1 * amp1 + amp2 * amp2 * (2 ** n - 1))\n        if prob > 0.92:\n            break\n                                  \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AC1B3EF0A2105", "submission_order": 1, "result": "WA", "execution_time": "1208 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef preparation(targets: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(len(targets))\n    qc.h(targets)\n    return qc\n\n\ndef diffusion(qc, targets: list[int]):\n    o = preparation(targets)\n\n    qc.compose(o.inverse(), inplace=True)\n    qc.x(targets)\n    qc.mcp(pi, targets[:-1], targets[-1])\n    qc.x(targets)\n    qc.compose(o, inplace=True)\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(preparation(list(range(n))), inplace=True)\n    qc.h(y)\n\n    theta_0 = asin(np.sqrt(1 / 2**n))\n    K = int(np.floor((pi / 2) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n        diffusion(qc, list(range(n)))\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AC1B3EF0A2105", "submission_order": 2, "result": "WA", "execution_time": "1326 ms", "memory": "157 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef preparation(targets: list[int]) -> QuantumCircuit:\n    qc = QuantumCircuit(len(targets))\n    qc.h(targets)\n    return qc\n\n\ndef diffusion(qc, targets: list[int]):\n    o = preparation(targets)\n\n    qc.compose(o.inverse(), inplace=True)\n    qc.x(targets)\n    qc.mcp(pi, targets[:-1], targets[-1])\n    qc.x(targets)\n    qc.compose(o, inplace=True)\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.compose(preparation(list(range(n))), inplace=True)\n    qc.h(y)\n\n    theta_0 = asin(np.sqrt(1 / 2**n))\n    K = int(np.floor((pi / 2) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n        diffusion(qc, list(range(n)))\n\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AC1B3EF0A2105", "submission_order": 3, "result": "RE", "execution_time": "1428 ms", "memory": "154 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, oracle: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(x)\n    qc.h(y)\n\n    theta_0 = asin(np.sqrt(1 / 2**n))\n    K = int(np.floor((pi / 2) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(oracle, inplace=True)\n\n        qc.h(range(n))\n        qc.x(range(n))\n        qc.mcp(pi, range(n - 1), n - 1)\n        qc.x(range(n))\n        qc.h(range(n))\n\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AC1B3EF0A2105", "submission_order": 4, "result": "WA", "execution_time": "1207 ms", "memory": "155 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, oracle: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(x)\n    qc.x(y)\n    qc.h(y)\n\n    theta_0 = asin(np.sqrt(1 / 2**n))\n    K = int(np.floor((pi / 2) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(oracle, inplace=True)\n\n        qc.h(range(n))\n        qc.x(range(n))\n        qc.mcp(pi, list(range(n - 1)), n - 1)\n        qc.x(range(n))\n        qc.h(range(n))\n\n    qc.h(y)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AC1B3EF0A2105", "submission_order": 5, "result": "AC", "execution_time": "1766 ms", "memory": "157 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, oracle: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(x)\n    qc.x(y)\n    qc.h(y)\n\n    theta_0 = asin(np.sqrt(1 / 2**n))\n    K = int(np.floor((pi / 2) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(oracle, inplace=True)\n\n        qc.h(range(n))\n        qc.x(range(n))\n        qc.mcp(pi, list(range(n - 1)), n - 1)\n        qc.x(range(n))\n        qc.h(range(n))\n\n    qc.h(y)\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AC5DC9EF1B1E4", "submission_order": 1, "result": "WA", "execution_time": "1513 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.h(range(n))  # メインの n 量子ビット\n    qc.h(n)  # 補助ビット\n\n    qc.compose(o, inplace=True)\n\n    qc.h(range(n))  # Hゲートを適用\n    qc.x(range(n))  # Xゲートを適用\n    qc.h(n-1)  # 最後のビットにHゲートを適用\n    qc.mcx(list(range(n-1)), n-1)  # マルチ制御Xゲート (制御は n-1 ビット)\n    qc.h(n-1)  # 再びHゲートを適用\n    qc.x(range(n))  # Xゲートを適用\n    qc.h(range(n))  # 再びHゲートを適用\n    \n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD065479D6959", "submission_order": 1, "result": "RE", "execution_time": "1642 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = math.asin(1 / (2 ** n) ** 0.5)\n    iterations = math.pi / (4 * theta)\n    for i in range(n):\n        qc.h(x[i])\n    for _ in range(iterations):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o.inverse(), inplace=True)\n        qc.compose(diffusion_oracle(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD065479D6959", "submission_order": 2, "result": "RE", "execution_time": "1741 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = math.asin(1 / (2 ** n) ** 0.5)\n    iterations = math.pi / (4 * theta)\n    for i in range(n):\n        qc.h(x[i])\n    for _ in range(iterations):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o.inverse(), inplace=True)\n        qc.compose(diffusion_oracle(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD065479D6959", "submission_order": 3, "result": "AC", "execution_time": "2265 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef diffusion_oracle(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        qc.x(i)\n    qc.append(ZGate().control(n - 1), range(n))\n    for i in range(n):\n        qc.x(i)\n        qc.h(i)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = math.asin(1 / (2 ** n) ** 0.5)\n    iterations = math.floor(math.pi / (4 * theta))\n    # print(theta, iterations)\n    for i in range(n):\n        qc.h(x[i])\n    diff = diffusion_oracle(n)\n    for _ in range(iterations):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o.inverse(), inplace=True)\n        qc.compose(diff, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 1, "result": "WA", "execution_time": "1216 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    qc.h(y)\n    \n    for _ in range(rounds_int-1):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion(n), inplace = True)\n\n    qc.compose(o, inplace=True)\n    \n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(np.pi, list(range(n)), y[0])\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))   \n\n    qc.h(y)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 2, "result": "WA", "execution_time": "1291 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    \n    \n    for _ in range(rounds_int-1):\n        qc.compose(o, inplace=True)\n        qc.compose(diffusion(n), inplace = True)\n\n    qc.compose(o, inplace=True)\n    \n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcx(list(range(n)), y[0])\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))   \n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 3, "result": "WA", "execution_time": "1341 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    \n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        qc.compose(diffusion(n), inplace = True)\n\n\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    \n    \n    for _ in range(rounds_int-):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        qc.compose(o, inplace= True)\n        qc.compose(diffusion(n), inplace = True)\n\n\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    \n    \n    for _ in range(rounds_int-):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        qc.compose(o, inplace= True)\n        qc.compose(diffusion(n), inplace = True)\n\n\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    \n    \n    for _ in range(rounds_int-):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        #qc.compose(o, inplace= True)\n        qc.compose(diffusion(n), inplace = True)\n\n\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 7, "result": "WA", "execution_time": "1651 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    \n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        qc.compose(diffusion(n), inplace = True)\n\n\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 8, "result": "WA", "execution_time": "1196 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    \n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        qc.compose(o, inplace = True)\n        qc.compose(diffusion(n), inplace = True)\n\n\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 9, "result": "WA", "execution_time": "1413 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    \n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        qc.compose(o, inplace = True)\n        qc.compose(diffusion(n), inplace = True)\n    \n    qc.compose(o, inplace=True)\n\n\n\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 10, "result": "WA", "execution_time": "1445 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    qc.h(y[0])\n    \n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        qc.compose(diffusion(n), inplace = True)\n    \n    qc.compose(o, inplace=True)\n\n\n    qc.h(y[0])\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AD4F844534BE8", "submission_order": 11, "result": "WA", "execution_time": "1226 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef diffusion(n):\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = np.pi\n    controls = list(range(n-1))\n    target = n-1\n\n    qc.h(range(n))\n\n    for i in range(n):\n        qc.x(i)\n    \n    qc.mcp(theta, list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(range(n))\n\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    n = n\n    rounds = np.round(np.pi/(4*(np.arcsin(np.sqrt(1/2**(n - 1)))))-1/2, 4)\n    rounds_int = int(np.round(rounds))\n\n    qc.h(x)\n    qc.h(y[0])\n    \n    \n    for _ in range(rounds_int):\n        qc.compose(o, inplace=True)\n        qc.z(y[0])\n        qc.compose(diffusion(n), inplace = True)\n    \n    \n\n\n    qc.h(y[0])\n    \n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AE0EA0AA82EE6", "submission_order": 1, "result": "RE", "execution_time": "1369 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nfrom math import sqrt, pi\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n\ndef b5(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\n\ndef calc_r(n: int) -> int:\n    val = pi * sqrt(2**n) / 4\n    for r in range(1, 1000):\n        if r > val:\n            break\n    return r - 1\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    for i in range(n + 1):\n        qc.h(i)\n    r = calc_r(n)\n    for i in range(r):\n        qc.compose(o, inplace=True)\n        b5(qc)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AE0EA0AA82EE6", "submission_order": 2, "result": "WA", "execution_time": "1792 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom math import sqrt, pi\n\ndef b4(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n\n    for i in range(n):\n        qc.x(i)\n\n\ndef b5(qc: QuantumCircuit) -> None:\n    n = qc.num_qubits\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    b4(qc)\n    for i in range(n):\n        qc.h(i)\n\n\ndef calc_r(n: int) -> int:\n    val = pi * sqrt(2**n) / 4\n    for r in range(1, 1000):\n        if r > val:\n            break\n    return r - 1\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    for i in range(n + 1):\n        qc.h(i)\n    r = calc_r(n)\n    for i in range(r):\n        qc.compose(o, inplace=True)\n        b5(qc)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AE0EA0AA82EE6", "submission_order": 3, "result": "RE", "execution_time": "1161 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom math import sqrt, pi\n\n\ndef b4(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n\n\ndef b5(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(b4(n), inplace=True)\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n\ndef calc_r(n: int) -> int:\n    val = pi * sqrt(2**n) / 4\n    for r in range(1, 1000):\n        if r > val:\n            break\n    return r - 1\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    for i in range(n + 1):\n        qc.h(i)\n    r = calc_r(n)\n    for i in range(r):\n        qc.compose(o, inplace=True)\n        qc.compose(b5, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_B8", "user": "AE0EA0AA82EE6", "submission_order": 4, "result": "WA", "execution_time": "1804 ms", "memory": "169 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\nfrom math import sqrt, pi\n\n\n# def oracle(n: int) -> QuantumCircuit:\n#     x, y = QuantumRegister(n), QuantumRegister(1)\n#     qc = QuantumCircuit(x, y)\n#     for i in range(n):\n#         qc.x(i)\n#     mcz = ZGate().control(n - 1)\n#     qc.append(mcz, range(n))\n#     for i in range(n):\n#         qc.x(i)\n#     return qc\n\n\ndef b4(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.x(i)\n    mcz = ZGate().control(n - 1)\n    qc.append(mcz, range(n))\n    for i in range(n):\n        qc.x(i)\n    return qc\n\n\ndef b5(n: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.compose(b4(n), inplace=True)\n    for i in range(n):\n        qc.h(i)\n    return qc\n\n\ndef calc_r(n: int) -> int:\n    val = pi * sqrt(2**n) / 4\n    for r in range(1, 1000):\n        if r > val:\n            break\n    return r - 1\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    for i in range(n + 1):\n        qc.h(i)\n    r = calc_r(n)\n    for i in range(r):\n        qc.compose(o, inplace=True)\n        qc.compose(b5(n), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A125FC47C4E44", "submission_order": 1, "result": "AC", "execution_time": "1852 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    \n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A34E5547A136B", "submission_order": 1, "result": "WA", "execution_time": "1206 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    for i in range(n):\n        qc.h(x[i])\n    qc.compose(o, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A4D49FFD36944", "submission_order": 1, "result": "AC", "execution_time": "1652 ms", "memory": "156 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A51501750170A", "submission_order": 1, "result": "RE", "execution_time": "1444 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cry(np.pi*2, n+1, 0)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A51501750170A", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.quantum_info import Statevector\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\nzero = Statevector([1,0])\nzero_state = zero.tensor(zero) # or zero_state = Statevector([1,0,0,0])\nprojector = zero_state.to_operator()\n\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cry(np.pi*2, n+1, 0)\n    qc.h(n+1)\n    qc.projector(n+1)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A53A8D30DFEDD", "submission_order": 1, "result": "AC", "execution_time": "2866 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A629B635CD321", "submission_order": 1, "result": "WA", "execution_time": "1481 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(o, inplace=True)\n    qc.cz(y[0],x[0])\n    qc.x(x[0])\n    qc.cz(y[0],x[0])\n    qc.x(x[0])\n    qc.cx(x[0],y[0])\n    qc.x(x[0])\n    qc.cx(x[0],y[0])\n    qc.x(x[0])\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A64F27D9AE53F", "submission_order": 1, "result": "AC", "execution_time": "1697 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y[0])\n    qc.h(y[0])\n    qc.compose(o, inplace=True)\n    qc.h(y[0])\n    qc.x(y[0])\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A7D23EB39F38C", "submission_order": 1, "result": "DLE", "execution_time": "1451 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    # Paso 1: Aplicar el oráculo O\n    qc.compose(o, qubits=x[:] + y[:], inplace=True)\n    \n    # Paso 2: Aplicar la puerta Z al qubit auxiliar y[0]\n    qc.z(y[0])\n    \n    # Paso 3: Aplicar nuevamente el oráculo O\n    qc.compose(o, qubits=x[:] + y[:], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A7D23EB39F38C", "submission_order": 2, "result": "AC", "execution_time": "1880 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    # Paso 1: Preparar el qubit auxiliar en el estado |-> = (|0⟩ - |1⟩)/√2\n    qc.x(y[0])  # Aplicar puerta X para obtener |1⟩\n    qc.h(y[0])  # Aplicar puerta Hadamard para obtener |->\n\n    # Paso 2: Aplicar el oráculo O\n    qc.compose(o, qubits=x[:] + y[:], inplace=True)\n\n    # Paso 3: Deshacer la preparación del qubit auxiliar\n    qc.h(y[0])  # Aplicar puerta Hadamard\n    qc.x(y[0])  # Aplicar puerta X para regresar al estado |0⟩\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A8B4C3DCE7D35", "submission_order": 1, "result": "AC", "execution_time": "1659 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    qc.h(n)\n    qc.compose(o, inplace=True)\n    qc.h(n)\n    qc.x(n)\n \n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "A9A069CA24D9E", "submission_order": 1, "result": "RE", "execution_time": "1663 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef w_state(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n\n    count = 1\n\n    # queue = [(a, b, control bit of CRy), ...]\n    queue = [(n // 2, n, 0)]\n\n    # breadth first search\n    while len(queue):\n        a, b, control = queue.pop(0)\n\n        if a == 0:\n            continue\n\n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n\n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n\n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n\n        count += 1\n\n    return qc\n\ndef reflect_w_state() -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(w_state(n).inverse(), inplace=True)\n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n    qc.compose(w_state(n), inplace=True)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = math.asin(1 / (n) ** 0.5)\n    iterations = math.floor(math.pi / (4 * theta))\n    # print(theta, iterations)\n    qc.compose(w_state(n), inplace=True)\n    reflect = reflect_w_state()\n    for _ in range(iterations):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o.inverse(), inplace=True)\n        qc.compose(reflect, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AAB808C117064", "submission_order": 1, "result": "AC", "execution_time": "1663 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport numpy as np\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AABE5100A2C0A", "submission_order": 1, "result": "WA", "execution_time": "1292 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(list(range(n)))\n    qc.h(list(range(n)))\n    qc.compose(o, inplace=True)\n    qc.h(list(range(n)))\n    qc.x(list(range(n)))\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AABE5100A2C0A", "submission_order": 2, "result": "AC", "execution_time": "1739 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AE21BD12F5C13", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AE21BD12F5C13", "submission_order": 2, "result": "AC", "execution_time": "1687 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.compose(o, inplace=True)\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AEE5BFDF8E24D", "submission_order": 1, "result": "AC", "execution_time": "1932 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y[0])\n    qc.h(y[0])\n\n    qc.compose(o, inplace=True)\n\n    qc.h(y[0])\n    qc.x(y[0])\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AF8F1BE10926F", "submission_order": 1, "result": "WA", "execution_time": "1217 ms", "memory": "155 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    y = QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    qc.h(x)  \n    qc.x(y) \n\n    qc.compose(o, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AF8F1BE10926F", "submission_order": 2, "result": "RE", "execution_time": "1394 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x = QuantumRegister(n)  \n    y = QuantumRegister(1)   \n    qc = QuantumCircuit(x, y)\n\n    qc.x(y)  \n\n    qc.compose(o, inplace=True)\n\n    qc.x(y) \n\n    qc.mct(x, y) \n\n    qc.x(y)  \n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AF8F1BE10926F", "submission_order": 3, "result": "RE", "execution_time": "1262 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x = QuantumRegister(n)  \n    y = QuantumRegister(1)   \n    qc = QuantumCircuit(x, y)\n\n    qc.x(y)  \n\n    qc.compose(o, inplace=True)\n\n    qc.x(y) \n    qc.mct(x, y)  \n    qc.x(y) \n\n    return qc\n'''"}
{"problem": "QPC003_EX1", "user": "AFB88AAF9AE3F", "submission_order": 1, "result": "AC", "execution_time": "2228 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(n)\n    qc.h(n)\n    qc.compose(o,inplace=True)\n    qc.h(n)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 1, "result": "RE", "execution_time": "1158 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi> tal que\n    la probabilidad de medir |L> es al menos 0.9.\n    \n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits y 1 auxiliar\n    \n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Definir registros cuánticos\n    x = QuantumRegister(n, 'x')  # Qubits para |x>\n    y = QuantumRegister(1, 'y')  # Qubit auxiliar\n    qc = QuantumCircuit(x, y)\n\n    def diffuser(n):\n        \"\"\"\n        Crea el operador de difusión (diffuser) para el Algoritmo de Grover.\n        \"\"\"\n        qc = QuantumCircuit(n)\n        qc.h(range(n))\n        qc.x(range(n))\n        \n        # Aplicar una puerta Z multi-controlada\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)  # Puerta Toffoli multi-controlada\n        qc.h(n-1)\n        \n        qc.x(range(n))\n        qc.h(range(n))\n        \n        # Convertir el circuito en una puerta\n        diffuser_gate = qc.to_gate()\n        diffuser_gate.name = \"Diffuser\"\n        return diffuser_gate\n    \n    # Paso 1: Preparar el qubit auxiliar en el estado |-> = (|0> - |1>)/sqrt(2)\n    qc.x(y[0])\n    qc.h(y[0])\n    \n    # Paso 2: Aplicar puertas Hadamard a todos los qubits para crear una superposición uniforme\n    qc.h(x)\n    \n    # Definir el operador de difusión\n    diffuser_gate = diffuser(n)\n    \n    # Calcular el número óptimo de iteraciones de Grover\n    N = 2**n\n    k = 1  # Número de soluciones (k=1 ya que L es único)\n    theta = math.asin(math.sqrt(k / N))\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n    \n    # Determinar el número de iteraciones permitidas por la restricción de profundidad\n    # Estimación de profundidad por iteración:\n    # - Oráculo O: profundidad 1\n    # - H y X en y: profundidad 2\n    # - Difusor: profundidad aproximadamente n (depende de la implementación)\n    # Asumimos una profundidad total aproximada por iteración\n    depth_per_iteration = 1 + 2 + 20  # Ajustar según n\n    max_iterations = math.floor(75 / depth_per_iteration)\n    iterations = min(optimal_iterations, max_iterations)\n    iterations = max(1, iterations)  # Al menos una iteración\n    \n    # Aplicar el algoritmo de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=x[:] + [y[0]], inplace=True)\n        \n        # Paso 4: Aplicar puertas H y X al qubit auxiliar para realizar phase kickback\n        qc.h(y[0])\n        qc.x(y[0])\n        \n        # Paso 5: Aplicar el operador de difusión\n        qc.append(diffuser_gate, qargs=x[:], inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 2, "result": "RE", "execution_time": "1139 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef diffuser(n):\n    \"\"\"\n    Crea el operador de difusión (diffuser) para el Algoritmo de Grover.\n    \"\"\"\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    qc.x(range(n))\n    \n    # Aplicar una puerta Z multi-controlada\n    qc.h(n-1)\n    qc.mcx(list(range(n-1)), n-1)  # Puerta Toffoli multi-controlada\n    qc.h(n-1)\n    \n    qc.x(range(n))\n    qc.h(range(n))\n    \n    # Convertir el circuito en una puerta\n    diffuser_gate = qc.to_gate()\n    diffuser_gate.name = \"Diffuser\"\n    return diffuser_gate\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi> tal que\n    la probabilidad de medir |L> es al menos 0.9.\n    \n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits y 1 auxiliar\n    \n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Definir registros cuánticos\n    x = QuantumRegister(n, 'x')  # Qubits para |x>\n    y = QuantumRegister(1, 'y')  # Qubit auxiliar\n    qc = QuantumCircuit(x, y)\n    \n    # Paso 1: Preparar el qubit auxiliar en el estado |-> = (|0> - |1>)/sqrt(2)\n    qc.x(y[0])\n    qc.h(y[0])\n    \n    # Paso 2: Aplicar puertas Hadamard a todos los qubits para crear una superposición uniforme\n    qc.h(x)\n    \n    # Definir el operador de difusión\n    diffuser_gate = diffuser(n)\n    \n    # Calcular el número óptimo de iteraciones de Grover\n    N = 2**n\n    k = 1  # Número de soluciones (k=1 ya que L es único)\n    theta = math.asin(math.sqrt(k / N))\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n    \n    # Determinar el número de iteraciones permitidas por la restricción de profundidad\n    # Estimación de profundidad por iteración:\n    # - Oráculo O: profundidad 1\n    # - H y X en y: profundidad 2\n    # - Difusor: profundidad aproximadamente n (depende de la implementación)\n    # Asumimos una profundidad total aproximada por iteración\n    depth_per_iteration = 1 + 2 + 20  # Ajustar según n\n    max_iterations = math.floor(75 / depth_per_iteration)\n    iterations = min(optimal_iterations, max_iterations)\n    iterations = max(1, iterations)  # Al menos una iteración\n    \n    # Aplicar el algoritmo de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=x[:] + [y[0]], inplace=True)\n        \n        # Paso 4: Aplicar puertas H y X al qubit auxiliar para realizar phase kickback\n        qc.h(y[0])\n        qc.x(y[0])\n        \n        # Paso 5: Aplicar el operador de difusión\n        qc.append(diffuser_gate, qargs=x[:], inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 3, "result": "RE", "execution_time": "1382 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi> tal que\n    la probabilidad de medir |L> es al menos 0.9.\n    \n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits y 1 auxiliar\n    \n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Definir registros cuánticos\n    x = QuantumRegister(n, 'x')  # Qubits para |x>\n    y = QuantumRegister(1, 'y')  # Qubit auxiliar\n    qc = QuantumCircuit(x, y)\n    \n    # Paso 1: Preparar el qubit auxiliar en el estado |-> = (|0> - |1>)/sqrt(2)\n    qc.x(y[0])\n    qc.h(y[0])\n    \n    # Paso 2: Aplicar puertas Hadamard a todos los qubits para crear una superposición uniforme\n    qc.h(x)\n        \n    # Calcular el número óptimo de iteraciones de Grover\n    N = 2**n\n    k = 1  # Número de soluciones (k=1 ya que L es único)\n    theta = math.asin(math.sqrt(k / N))\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n    \n    # Determinar el número de iteraciones permitidas por la restricción de profundidad\n    # Estimación de profundidad por iteración:\n    # - Oráculo O: profundidad 1\n    # - H y X en y: profundidad 2\n    # - Difusor: profundidad aproximadamente n (depende de la implementación)\n    # Asumimos una profundidad total aproximada por iteración\n    depth_per_iteration = 1 + 2 + 20  # Ajustar según n\n    max_iterations = math.floor(75 / depth_per_iteration)\n    iterations = min(optimal_iterations, max_iterations)\n    iterations = max(1, iterations)  # Al menos una iteración\n    \n    # Aplicar el algoritmo de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=x[:] + [y[0]], inplace=True)\n        \n        # Paso 4: Aplicar puertas H y X al qubit auxiliar para realizar phase kickback\n        qc.h(y[0])\n        qc.x(y[0])\n        \n        # Paso 5: Aplicar el operador de difusión\n        qc.h(range(n))\n        qc.x(range(n))\n        \n                      # Aplicar una puerta Z multi-controlada\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)  # Puerta Toffoli multi-controlada\n        qc.h(n-1)\n        \n        qc.x(range(n))\n        qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 4, "result": "WA", "execution_time": "1639 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi⟩ tal que\n    la probabilidad de medir |L⟩ es al menos 0.9.\n\n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits\n\n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Definir el registro cuántico\n    x = QuantumCircuit(n)\n    qc = QuantumCircuit(n)\n    \n    # Paso 1: Aplicar puertas Hadamard a todos los qubits para crear una superposición uniforme\n    qc.h(range(n))\n    \n    # Paso 2: Determinar el número óptimo de iteraciones de Grover\n    # Número total de estados\n    N = 2**n\n    # Número de soluciones (k=1, ya que L es único)\n    k = 1\n    # Calcular el ángulo theta\n    theta = math.asin(math.sqrt(k / N))\n    # Número óptimo de iteraciones\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n    \n    # Estimar la profundidad por iteración\n    # Cada iteración incluye:\n    # - Oráculo O: profundidad 1\n    # - Difusor: profundidad aproximada 4 (H, X, MCX, etc.)\n    # Total por iteración: ~5\n    depth_per_iteration = 5\n    max_depth = 75\n    # Calcular el número máximo de iteraciones sin exceder la profundidad\n    max_iterations = min(optimal_iterations, max_depth // depth_per_iteration)\n    # Asegurarse de que al menos se realice una iteración\n    iterations = max(1, max_iterations)\n       \n    # Aplicar iteraciones de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=range(n), inplace=True)\n        \n        # Paso 4: Aplicar el operador de difusión\n        # Aplicar puertas Hadamard a todos los qubits\n        qc.h(range(n))\n        # Aplicar puertas X a todos los qubits\n        qc.x(range(n))\n        \n        # Aplicar una puerta Z multi-controlada\n        # Implementación de una puerta CCZ para n=2 o MCZ para n>2\n        if n == 1:\n            qc.z(0)\n        elif n == 2:\n            qc.cz(0, 1)\n        else:\n            # Aplicar Hadamard al último qubit\n            qc.h(n-1)\n            # Aplicar MCX con los primeros n-1 qubits como controles y el último como objetivo\n            qc.mcx(list(range(n-1)), n-1)\n            # Aplicar nuevamente Hadamard al último qubit\n            qc.h(n-1)\n        \n        # Aplicar puertas X a todos los qubits\n        qc.x(range(n))\n        # Aplicar puertas Hadamard a todos los qubits\n        qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 5, "result": "WA", "execution_time": "1872 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi⟩ tal que\n    la probabilidad de medir |L⟩ es al menos 0.9.\n\n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits\n\n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Definir el registro cuántico\n    x = QuantumCircuit(n)\n    qc = QuantumCircuit(n)\n    \n    # Paso 1: Aplicar puertas Hadamard a todos los qubits para crear una superposición uniforme\n    qc.h(range(n))\n    \n    # Paso 2: Determinar el número óptimo de iteraciones de Grover\n    # Número total de estados\n    N = 2**n\n    # Número de soluciones (k=1, ya que L es único)\n    k = 1\n    # Calcular el ángulo theta\n    theta = math.asin(math.sqrt(k / N))\n    # Número óptimo de iteraciones\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n    \n    # Estimar la profundidad por iteración\n    # Cada iteración incluye:\n    # - Oráculo O: profundidad 1\n    # - Difusor: profundidad aproximada 4 (H, X, MCX, etc.)\n    # Total por iteración: ~5\n    depth_per_iteration = 5\n    max_depth = 75\n    # Calcular el número máximo de iteraciones sin exceder la profundidad\n    max_iterations = min(optimal_iterations, max_depth // depth_per_iteration)\n    # Asegurarse de que al menos se realice una iteración\n    iterations = max(1, max_iterations)\n       \n    # Aplicar iteraciones de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=range(n), inplace=True)\n        \n        # Paso 4: Aplicar el operador de difusión\n        qc.h(range(n))\n        qc.x(range(n))\n        \n                      # Aplicar una puerta Z multi-controlada\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)  # Puerta Toffoli multi-controlada\n        qc.h(n-1)\n        \n        qc.x(range(n))\n        qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 6, "result": "WA", "execution_time": "1241 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi⟩ tal que\n    la probabilidad de medir |L⟩ es al menos 0.9.\n\n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits\n\n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Inicializar el circuito cuántico con n qubits\n    qc = QuantumCircuit(n)\n\n    # Definir el qubit auxiliar como el último qubit (n-1)\n    y = n - 1\n\n    # Paso 1: Preparar el qubit auxiliar y en el estado |-> = (|0⟩ - |1⟩)/sqrt(2)\n    qc.x(y)      # Aplica X para convertir |0⟩ en |1⟩\n    qc.h(y)      # Aplica Hadamard para obtener |->\n\n    # Paso 2: Aplicar puertas Hadamard a todos los qubits excepto el auxiliar para crear una superposición uniforme\n    if n > 1:\n        qc.h(range(n - 1))\n    else:\n        qc.h(y)  # Si n=1, aplicar H al único qubit\n\n    # Calcular el número óptimo de iteraciones de Grover\n    # Número total de estados\n    N = 2**n\n    # Número de soluciones (k=1, ya que L es único)\n    k = 1\n    # Calcular el ángulo theta\n    theta = math.asin(math.sqrt(k / N))\n    # Número óptimo de iteraciones\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n\n    # Estimar la profundidad por iteración\n    # Cada iteración incluye:\n    # - Oráculo O: profundidad 1\n    # - Difusor: profundidad aproximada (dependiendo de n)\n    # Para simplificar, asumimos una profundidad por iteración de 3n + 3\n    depth_per_iteration = 3 * n + 3\n    max_depth = 75\n    initial_depth = 2 + (n - 1 if n > 1 else 1)  # X y H en y qubit, H en otros qubits\n\n    # Calcular el número máximo de iteraciones sin exceder la profundidad\n    remaining_depth = max_depth - initial_depth\n    if remaining_depth < depth_per_iteration:\n        iterations = 1  # Al menos una iteración\n    else:\n        iterations = min(optimal_iterations, remaining_depth // depth_per_iteration)\n\n    # Asegurarse de que al menos se realice una iteración\n    iterations = max(1, iterations)\n\n    # Definir el operador de difusión (diffuser)\n    def diffuser_operator(diffuser):\n        \"\"\"\n        Crea el operador de difusión para el Algoritmo de Grover.\n        \"\"\"\n        #diffuser = QuantumCircuit(n_qubits, name='Diffuser')\n        diffuser.h(range(n))\n        diffuser.x(range(n))\n        \n        # Aplicar la puerta Z multi-controlada\n        if n == 1:\n            diffuser.z(0)\n        elif n == 2:\n            diffuser.cz(0, 1)\n        else:\n            diffuser.h(n - 1)\n            diffuser.mcx(list(range(n - 1)), n - 1)  # Puerta Toffoli multi-controlada\n            diffuser.h(n - 1)\n        \n        diffuser.x(range(n))\n        diffuser.h(range(n))\n        \n        #return diffuser.to_gate()\n\n    #diffuser_gate = diffuser_operator(n)\n\n    # Aplicar iteraciones de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=range(n), inplace=True)\n\n        # Paso 4: Aplicar el operador de difusión\n        #qc.append(diffuser_gate, qargs=range(n))\n        diffuser_operator(qc)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 7, "result": "RE", "execution_time": "1301 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi⟩ tal que\n    la probabilidad de medir |L⟩ es al menos 0.9.\n\n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits\n\n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Inicializar el circuito cuántico con n qubits\n    qc = QuantumCircuit(n)\n\n    # Definir el qubit auxiliar como el último qubit (n-1)\n    y = n - 1\n\n    # Paso 1: Preparar el qubit auxiliar y en el estado |-> = (|0⟩ - |1⟩)/sqrt(2)\n    qc.x(y)      # Aplica X para convertir |0⟩ en |1⟩\n    qc.h(y)      # Aplica Hadamard para obtener |->\n\n    # Paso 2: Aplicar puertas Hadamard a todos los qubits excepto el auxiliar para crear una superposición uniforme\n    if n > 1:\n        qc.h(range(n - 1))\n    else:\n        qc.h(y)  # Si n=1, aplicar H al único qubit\n\n    # Calcular el número óptimo de iteraciones de Grover\n    # Número total de estados\n    N = 2**n\n    # Número de soluciones (k=1, ya que L es único)\n    k = 1\n    # Calcular el ángulo theta\n    theta = math.asin(math.sqrt(k / N))\n    # Número óptimo de iteraciones\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n\n    # Estimar la profundidad por iteración\n    # Cada iteración incluye:\n    # - Oráculo O: profundidad 1\n    # - Difusor: profundidad aproximada (dependiendo de n)\n    # Para simplificar, asumimos una profundidad por iteración de 3n + 3\n    depth_per_iteration = 3 * n + 3\n    max_depth = 75\n    initial_depth = 2 + (n - 1 if n > 1 else 1)  # X y H en y qubit, H en otros qubits\n\n    # Calcular el número máximo de iteraciones sin exceder la profundidad\n    remaining_depth = max_depth - initial_depth\n    if remaining_depth < depth_per_iteration:\n        iterations = 1  # Al menos una iteración\n    else:\n        iterations = min(optimal_iterations, remaining_depth // depth_per_iteration)\n\n    # Asegurarse de que al menos se realice una iteración\n    iterations = max(1, iterations)\n\n    # Definir el operador de difusión (diffuser)\n    def diffuser_operator(n_qubits):\n        \"\"\"\n        Crea el operador de difusión para el Algoritmo de Grover.\n        \"\"\"\n        diffuser = QuantumCircuit(n_qubits, name='Diffuser')\n        diffuser.h(range(n_qubits))\n        diffuser.x(range(n_qubits))\n        \n        # Aplicar la puerta Z multi-controlada\n        if n_qubits == 1:\n            diffuser.z(0)\n        elif n_qubits == 2:\n            diffuser.cz(0, 1)\n        else:\n            diffuser.h(n_qubits - 1)\n            diffuser.mcx(list(range(n_qubits - 1)), n_qubits - 1)  # Puerta Toffoli multi-controlada\n            diffuser.h(n_qubits - 1)\n        \n        diffuser.x(range(n_qubits))\n        diffuser.h(range(n_qubits))\n        \n        return diffuser.to_gate()\n\n    diffuser_gate = diffuser_operator(n)\n\n    # Aplicar iteraciones de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=range(n), inplace=True)\n\n        # Paso 4: Aplicar el operador de difusión\n        qc.append(diffuser_gate, qargs=range(n), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 8, "result": "WA", "execution_time": "1653 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi⟩ tal que\n    la probabilidad de medir |L⟩ es al menos 0.9.\n\n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits\n\n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Definir el registro cuántico\n    x = QuantumCircuit(n)\n    qc = QuantumCircuit(n)\n    \n    # Paso 1: Aplicar puertas Hadamard a todos los qubits para crear una superposición uniforme\n    qc.h(range(n))\n    \n    # Paso 2: Determinar el número óptimo de iteraciones de Grover\n    # Número total de estados\n    N = 2**n\n    # Número de soluciones (k=1, ya que L es único)\n    k = 1\n    # Calcular el ángulo theta\n    theta = math.asin(math.sqrt(k / N))\n    # Número óptimo de iteraciones\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n    \n    # Estimar la profundidad por iteración\n    # Cada iteración incluye:\n    # - Oráculo O: profundidad 1\n    # - Difusor: profundidad aproximada 4 (H, X, MCX, etc.)\n    # Total por iteración: ~5\n    depth_per_iteration = 5\n    max_depth = 75\n    # Calcular el número máximo de iteraciones sin exceder la profundidad\n    max_iterations = min(optimal_iterations, max_depth // depth_per_iteration)\n    # Asegurarse de que al menos se realice una iteración\n    iterations = max(1, max_iterations)\n       \n    # Aplicar iteraciones de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=range(n), inplace=True)\n        \n        # Paso 4: Aplicar el operador de difusión\n        qc.h(range(n))\n        qc.x(range(n))\n        \n                      # Aplicar una puerta Z multi-controlada\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)  # Puerta Toffoli multi-controlada\n        qc.h(n-1)\n        \n        qc.x(range(n))\n        qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A1B1A8AD4E4C5", "submission_order": 9, "result": "RE", "execution_time": "1159 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    \"\"\"\n    Implementa un circuito cuántico que prepara el estado |psi⟩ tal que\n    la probabilidad de medir |L⟩ es al menos 0.9.\n\n    Parámetros:\n    - n: Número de qubits\n    - o: Oráculo O como QuantumCircuit de profundidad 1 que actúa sobre n qubits y 1 auxiliar\n\n    Retorna:\n    - qc: QuantumCircuit que implementa la operación deseada\n    \"\"\"\n    # Definir los registros cuánticos\n    x = QuantumRegister(n, 'x')  # Qubits para |x⟩\n    y = QuantumRegister(1, 'y')  # Qubit auxiliar\n    qc = QuantumCircuit(x, y)\n    \n    # Paso 1: Preparar el qubit auxiliar en el estado |-> = (|0⟩ - |1⟩)/sqrt(2)\n    qc.x(y[0])      # Aplicar puerta X para |1⟩\n    qc.h(y[0])      # Aplicar puerta Hadamard para |->\n\n    # Paso 2: Aplicar puertas Hadamard a todos los qubits de x para crear una superposición uniforme\n    qc.h(x)\n\n    # Calcular el número óptimo de iteraciones de Grover\n    N = 2**n\n    k = 1  # Número de soluciones (único L)\n    theta = math.asin(math.sqrt(k / N))\n    optimal_iterations = int(math.floor((math.pi / (4 * theta)) - 0.5))\n    \n    # Estimar la profundidad por iteración\n    # Cada iteración incluye:\n    # - Oráculo O: profundidad 1\n    # - Difusor: aproximadamente 4n + 2 (puertas H, X, MCX, etc.)\n    # Suponemos una profundidad por iteración de 5n para mayor seguridad\n    depth_per_iteration = 5 * n\n    max_depth = 75\n    initial_depth = 2 + n  # X and H on y qubit and H on x qubits\n\n    # Calcular el número máximo de iteraciones sin exceder la profundidad\n    remaining_depth = max_depth - initial_depth\n    if remaining_depth < depth_per_iteration:\n        iterations = 1  # Al menos una iteración\n    else:\n        iterations = min(optimal_iterations, remaining_depth // depth_per_iteration)\n    \n    # Asegurarse de que al menos se realice una iteración\n    iterations = max(1, iterations)\n    \n    # Definir el operador de difusión (diffuser) sin usar to_gate()\n    def apply_diffuser(circuit, qubits):\n        \"\"\"\n        Aplica el operador de difusión de Grover al circuito dado sobre los qubits especificados.\n        \"\"\"\n        # Paso 1: Aplicar puertas Hadamard a todos los qubits\n        circuit.h(qubits)\n        \n        # Paso 2: Aplicar puertas X a todos los qubits\n        circuit.x(qubits)\n        \n        # Paso 3: Aplicar la puerta Z multi-controlada\n        if len(qubits) == 1:\n            # Caso n=1: Aplicar puerta Z directamente\n            circuit.z(qubits[0])\n        elif len(qubits) == 2:\n            # Caso n=2: Aplicar puerta CZ\n            circuit.cz(qubits[0], qubits[1])\n        else:\n            # Caso n > 2: Implementar una puerta Z multi-controlada\n            # Convertir la última qubit a Z mediante MCX y H\n            circuit.h(qubits[-1])\n            circuit.mcx(qubits[:-1], qubits[-1])  # Puerta Toffoli multi-controlada\n            circuit.h(qubits[-1])\n        \n        # Paso 4: Aplicar puertas X a todos los qubits\n        circuit.x(qubits)\n        \n        # Paso 5: Aplicar puertas Hadamard a todos los qubits\n        circuit.h(qubits)\n    \n    # Aplicar iteraciones de Grover\n    for _ in range(iterations):\n        # Paso 3: Aplicar el oráculo O\n        qc.compose(o, qubits=x[:] + [y[0]], inplace=True)\n        \n        # Paso 4: Aplicar el operador de difusión\n        apply_diffuser(qc, x)\n    \n    # Paso 5: Medir los qubits de x (opcional, dependiendo de la evaluación)\n    # qc.measure_all()\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A2755435ACE6F", "submission_order": 1, "result": "RE", "execution_time": "2425 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gates to all qubits\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    # Apply the oracle circuit\n    qc.compose(o, inplace=True)\n    \n    # Apply the inverse quantum Fourier transform\n    for qubit in range(n):\n        for j in range(qubit):\n            qc.cu1(-2 * math.pi / 2**(qubit - j), j, qubit)\n        qc.h(qubit)\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 1, "result": "WA", "execution_time": "2031 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.compose(o,inplace=True)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 2, "result": "WA", "execution_time": "2059 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    for i in range(n):\n        qc.compose(o,inplace=True)\n        qc.h(i)\n        qc.z(i)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 3, "result": "RE", "execution_time": "1764 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n+1))\n        qc.z(n)\n        qc.append(o,qargs = range(n+1))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 4, "result": "RE", "execution_time": "1859 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 5, "result": "WA", "execution_time": "1922 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 6, "result": "RE", "execution_time": "1847 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 7:\n        return grover(n,o)\n    else:\n        for i in range(n):\n            qc.h(i)\n        for _ in range(2):\n            qc.compose(o)\n            qc.compose(uniform_one_hot)\n            for i in range(n):\n                qc.x(i)\n            qc.compose(ZGate().control(n-1))\n            for i in range(n):\n                qc.x(i)\n            qc.compose(uniform_one_hot)\n        return qc\n        \n \n    return qc\n\ndef grover(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n\n\ndef uniform_one_hot(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 7, "result": "WA", "execution_time": "1992 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 7:\n        return grover(n,o)\n    else:\n        for i in range(n):\n            qc.h(i)\n        for _ in range(2):\n            qc.compose(o)\n            qc.compose(uniform_one_hot(n))\n            for i in range(n):\n                qc.x(i)\n            qc.compose(ZGate().control(n-1))\n            for i in range(n):\n                qc.x(i)\n            qc.compose(uniform_one_hot(n))\n        return qc\n\ndef grover(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n\n\ndef uniform_one_hot(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 8, "result": "WA", "execution_time": "2200 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 7:\n        return grover(n,o)\n    else:\n        for i in range(n):\n            qc.h(i)\n        for _ in range(2):\n            qc.compose(o)\n            qc.compose(uniform_one_hot(n))\n            for i in range(n):\n                qc.x(i)\n            qc.compose(ZGate().control(n-1))\n            for i in range(n):\n                qc.x(i)\n            qc.compose(uniform_one_hot(n).inverse())\n        return qc\n\ndef grover(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n\n\ndef uniform_one_hot(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 9, "result": "WA", "execution_time": "1913 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 7:\n        return grover(n,o)\n    else:\n        for i in range(n):\n            qc.h(i)\n        for _ in range(2):\n            qc.compose(o)\n            qc.compose(uniform_one_hot(n).inverse())\n            for i in range(n):\n                qc.x(i)\n            qc.compose(ZGate().control(n-1))\n            for i in range(n):\n                qc.x(i)\n            qc.compose(uniform_one_hot(n))\n        return qc\n\ndef grover(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n\n\ndef uniform_one_hot(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 10, "result": "WA", "execution_time": "1875 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 7:\n        return grover(n,o)\n    else:\n        for i in range(n):\n            qc.h(i)\n        for _ in range(2):\n            qc.compose(o, inplace=True)\n            qc.compose(uniform_one_hot(n).inverse(), inplace=True)\n            for i in range(n):\n                qc.x(i)\n            qc.compose(ZGate().control(n-1), inplace=True)\n            for i in range(n):\n                qc.x(i)\n            qc.compose(uniform_one_hot(n), inplace=True)\n        return qc\n\ndef grover(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.append(o,qargs = range(n))\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.append(ZGate().control(n-1),qargs = range(n))\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n\n\ndef uniform_one_hot(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 11, "result": "WA", "execution_time": "1846 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 7:\n        return grover(n,o)\n    else:\n        for i in range(n):\n            qc.h(i)\n        for _ in range(2):\n            qc.compose(o, inplace=True)\n            qc.compose(uniform_one_hot(n).inverse(), inplace=True)\n            for i in range(n):\n                qc.x(i)\n            qc.compose(ZGate().control(n-1), inplace=True)\n            for i in range(n):\n                qc.x(i)\n            qc.compose(uniform_one_hot(n), inplace=True)\n        return qc\n\ndef grover(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        for i in range(n):\n            qc.x(i)\n        qc.compose(ZGate().control(n-1), inplace=True)\n        for i in range(n):\n            qc.x(i)\n        for i in range(n):\n            qc.h(i)\n    return qc\n\n\ndef uniform_one_hot(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 12, "result": "WA", "execution_time": "1932 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 7:\n        return grover(n,o)\n    else:\n        for i in range(n):\n            qc.h(i)\n        for _ in range(2):\n            qc.compose(o, inplace=True)\n            qc.compose(uniform_one_hot(n).inverse(), inplace=True)\n            qc.compose(reflect(n), inplace=True)\n            qc.compose(uniform_one_hot(n), inplace=True)\n        return qc\n\ndef grover(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        qc.compose(reflect(n), inplace=True)\n        for i in range(n):\n            qc.h(i)\n    return qc\n\ndef reflect(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.compose(ZGate().control(n-1), inplace=True)\n    qc.x(range(n))\n    return qc\n\n\ndef uniform_one_hot(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_EX2", "user": "A6E427F589D3B", "submission_order": 13, "result": "AC", "execution_time": "2315 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\nimport numpy as np\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n <= 7:\n        return grover(n,o)\n    else:\n        qc.compose(uniform_one_hot(n), inplace=True)\n        for _ in range(2):\n            qc.compose(o, inplace=True)\n            qc.compose(uniform_one_hot(n).inverse(), inplace=True)\n            qc.compose(reflect(n), inplace=True)\n            qc.compose(uniform_one_hot(n), inplace=True)\n        return qc\n\ndef grover(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:-\n    for i in range(n):\n        qc.h(i)\n    row = [math.sin((2*r+1)*math.asin(2**(-n/2)))**2 for r in range(10)]\n    r = np.argmax(row)\n    for _ in range(r):\n        qc.compose(o, inplace=True)\n        for i in range(n):\n            qc.h(i)\n        qc.compose(reflect(n), inplace=True)\n        for i in range(n):\n            qc.h(i)\n    return qc\n\ndef reflect(n:int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.compose(ZGate().control(n-1), inplace=True)\n    qc.x(range(n))\n    return qc\n\n\ndef uniform_one_hot(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    n_code = bin(n)[2:]\n    m = [0]\n    for i in range(len(n_code)):\n        if n_code[i] == \"1\":\n            m.append(m[-1]+2**(len(n_code)-i-1))\n    qc.x(0)\n    for i in range(1,len(m)-1):\n        split_one_hot(qc,m[i-1],m[i],(m[i]-m[i-1])/(n-m[i-1]))\n    for j in range(1,len(m)):\n        for k in range(1,m[j]-m[j-1]):\n            split_one_hot(qc,m[j-1]+k-2**int(math.log2(k)),m[j-1]+k,1/2)\n\n    return qc\ndef split_one_hot(qc,m1,m2,l):\n    print(m1,m2,l)\n    qc.cry(2*math.acos(math.sqrt(l)),m1,m2)\n    qc.cx(m2,m1)\n'''"}
{"problem": "QPC003_EX2", "user": "A83F0EBC0A5F4", "submission_order": 1, "result": "RE", "execution_time": "1479 ms", "memory": "154 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    # sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef split_state(qc: QuantumCircuit, targets: list[int], proportions: list[float]):\n    sum_p = sum(proportions)\n    proportions = [p / sum_p for p in proportions]\n    for i in range(1, len(targets)):\n        qc.cry(\n            asin(sqrt((1 - sum(proportions[:i])) / (1 - sum(proportions[: i - 1]))))\n            * 2,\n            targets[i - 1],\n            targets[i],\n        )\n    for i in range(1, len(targets)):\n        qc.cx(targets[i], targets[i - 1])\n\n\ndef solve_main(qc: QuantumCircuit, i0: int, i1: int):\n    if i1 - i0 <= 1:\n        return\n    i = (i0 + i1) // 2\n    split_state(qc, [i0, i], [len(range(i0, i)), len(range(i, i1))])\n    solve_main(qc, i0, i)\n    solve_main(qc, i, i1)\n\n\ndef prep_A6(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    solve_main(qc, 0, n)\n\n    return qc\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    prep_qc = prep_A6(n)\n    # Write your code here:\n\n    qc.compose(prep_qc, inplace=True)\n\n    theta_0 = asin(np.sqrt(1 / n))\n    K = int(np.floor((pi / 2 - theta_0) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n\n        qc.compose(prep_qc.inverse(), inplace=True)\n        qc.x(range(n))\n        qc.mcp(pi, list(range(n - 1)), n - 1)\n        qc.x(range(n))\n        qc.compose(prep_qc, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A83F0EBC0A5F4", "submission_order": 2, "result": "WA", "execution_time": "1775 ms", "memory": "160 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef split_state(qc: QuantumCircuit, targets: list[int], proportions: list[float]):\n    sum_p = sum(proportions)\n    proportions = [p / sum_p for p in proportions]\n    for i in range(1, len(targets)):\n        qc.cry(\n            asin(sqrt((1 - sum(proportions[:i])) / (1 - sum(proportions[: i - 1]))))\n            * 2,\n            targets[i - 1],\n            targets[i],\n        )\n    for i in range(1, len(targets)):\n        qc.cx(targets[i], targets[i - 1])\n\n\ndef solve_main(qc: QuantumCircuit, i0: int, i1: int):\n    if i1 - i0 <= 1:\n        return\n    i = (i0 + i1) // 2\n    split_state(qc, [i0, i], [len(range(i0, i)), len(range(i, i1))])\n    solve_main(qc, i0, i)\n    solve_main(qc, i, i1)\n\n\ndef prep_A6(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    solve_main(qc, 0, n)\n\n    return qc\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    prep_qc = prep_A6(n)\n    # Write your code here:\n\n    qc.compose(prep_qc, inplace=True)\n\n    theta_0 = asin(sqrt(1 / n))\n    K = int(np.floor((pi / 2 + theta_0) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n\n        qc.compose(prep_qc.inverse(), inplace=True)\n        qc.x(range(n))\n        qc.mcp(pi, list(range(n - 1)), n - 1)\n        qc.x(range(n))\n        qc.compose(prep_qc, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A83F0EBC0A5F4", "submission_order": 3, "result": "WA", "execution_time": "1850 ms", "memory": "161 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef split_state(qc: QuantumCircuit, targets: list[int], proportions: list[float]):\n    sum_p = sum(proportions)\n    proportions = [p / sum_p for p in proportions]\n    for i in range(1, len(targets)):\n        qc.cry(\n            asin(sqrt((1 - sum(proportions[:i])) / (1 - sum(proportions[: i - 1]))))\n            * 2,\n            targets[i - 1],\n            targets[i],\n        )\n    for i in range(1, len(targets)):\n        qc.cx(targets[i], targets[i - 1])\n\n\ndef solve_main(qc: QuantumCircuit, i0: int, i1: int):\n    if i1 - i0 <= 1:\n        return\n    i = (i0 + i1) // 2\n    split_state(qc, [i0, i], [len(range(i0, i)), len(range(i, i1))])\n    solve_main(qc, i0, i)\n    solve_main(qc, i, i1)\n\n\ndef prep_A6(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    solve_main(qc, 0, n)\n\n    return qc\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve_7(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(8)\n    prep_qc = prep_A6(8)\n    # Write your code here:\n\n    qc.compose(prep_qc, inplace=True)\n\n    theta_0 = asin(sqrt(1 / 8))\n    K = int(np.round((pi / 2 - theta_0) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n\n        qc.compose(prep_qc.inverse(), inplace=True)\n        qc.x(range(8))\n        qc.mcp(pi, list(range(8 - 1)), 8 - 1)\n        qc.x(range(8))\n        qc.compose(prep_qc, inplace=True)\n\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    if n == 7:\n        return solve_7(n, o)\n    qc = QuantumCircuit(n)\n    prep_qc = prep_A6(n)\n    # Write your code here:\n\n    qc.compose(prep_qc, inplace=True)\n\n    theta_0 = asin(sqrt(1 / n))\n    K = int(np.round((pi / 2 - theta_0) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n\n        qc.compose(prep_qc.inverse(), inplace=True)\n        qc.x(range(n))\n        qc.mcp(pi, list(range(n - 1)), n - 1)\n        qc.x(range(n))\n        qc.compose(prep_qc, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A83F0EBC0A5F4", "submission_order": 4, "result": "AC", "execution_time": "1674 ms", "memory": "160 MiB", "code": "'''python\nfrom math import (\n    pi,\n    # degrees,\n    # radians,\n    asin,\n    # acos,\n    # atan2,\n    sqrt,\n    # sin,\n    # cos,\n    # tan\n)\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# from qiskit.circuit.library.standard_gates import (\n#     C3XGate,\n#     C3SXGate,\n#     C4XGate,\n#     CCXGate,\n#     DCXGate,\n#     CHGate,\n#     CPhaseGate,\n#     CRXGate,\n#     CRYGate,\n#     CRZGate,\n#     CSwapGate,\n#     CSXGate,\n#     CUGate,\n#     CU1Gate,\n#     CU3Gate,\n#     CXGate,\n#     CYGate,\n#     CZGate,\n#     CCZGate,\n#     HGate,\n#     IGate,\n#     MCPhaseGate,\n#     PhaseGate,\n#     RCCXGate,\n#     RC3XGate,\n#     RXGate,\n#     RXXGate,\n#     RYGate,\n#     RYYGate,\n#     RZGate,\n#     RZZGate,\n#     RZXGate,\n#     XXMinusYYGate,\n#     XXPlusYYGate,\n#     ECRGate,\n#     SGate,\n#     SdgGate,\n#     CSGate,\n#     CSdgGate,\n#     SwapGate,\n#     iSwapGate,\n#     SXGate,\n#     SXdgGate,\n#     TGate,\n#     TdgGate,\n#     UGate,\n#     U1Gate,\n#     U2Gate,\n#     U3Gate,\n#     XGate,\n#     YGate,\n#     ZGate,\n# )\n\n\ndef split_state(qc: QuantumCircuit, targets: list[int], proportions: list[float]):\n    sum_p = sum(proportions)\n    proportions = [p / sum_p for p in proportions]\n    for i in range(1, len(targets)):\n        qc.cry(\n            asin(sqrt((1 - sum(proportions[:i])) / (1 - sum(proportions[: i - 1]))))\n            * 2,\n            targets[i - 1],\n            targets[i],\n        )\n    for i in range(1, len(targets)):\n        qc.cx(targets[i], targets[i - 1])\n\n\ndef solve_main(qc: QuantumCircuit, i0: int, i1: int):\n    if i1 - i0 <= 1:\n        return\n    i = (i0 + i1) // 2\n    split_state(qc, [i0, i], [len(range(i0, i)), len(range(i, i1))])\n    solve_main(qc, i0, i)\n    solve_main(qc, i, i1)\n\n\ndef prep_A6(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    solve_main(qc, 0, n)\n\n    return qc\n\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef solve_2(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(4)\n    prep_qc = prep_A6(4)\n    # Write your code here:\n\n    qc.compose(prep_qc, inplace=True)\n\n    theta_0 = asin(sqrt(1 / 4))\n    K = int(np.round((pi / 2 - theta_0) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n\n        qc.compose(prep_qc.inverse(), inplace=True)\n        qc.x(range(4))\n        qc.mcp(pi, list(range(4 - 1)), 4 - 1)\n        qc.x(range(4))\n        qc.compose(prep_qc, inplace=True)\n\n    return qc\n\n\ndef solve_7(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(8)\n    prep_qc = prep_A6(8)\n    # Write your code here:\n\n    qc.compose(prep_qc, inplace=True)\n\n    theta_0 = asin(sqrt(1 / 8))\n    K = int(np.round((pi / 2 - theta_0) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n\n        qc.compose(prep_qc.inverse(), inplace=True)\n        qc.x(range(8))\n        qc.mcp(pi, list(range(8 - 1)), 8 - 1)\n        qc.x(range(8))\n        qc.compose(prep_qc, inplace=True)\n\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    if n == 2:\n        return solve_2(n, o)\n    if n == 7:\n        return solve_7(n, o)\n    qc = QuantumCircuit(n)\n    prep_qc = prep_A6(n)\n    # Write your code here:\n\n    qc.compose(prep_qc, inplace=True)\n\n    theta_0 = asin(sqrt(1 / n))\n    K = int(np.round((pi / 2 - theta_0) / theta_0 / 2))\n    for _ in range(K):\n        qc.compose(o, inplace=True)\n\n        qc.compose(prep_qc.inverse(), inplace=True)\n        qc.x(range(n))\n        qc.mcp(pi, list(range(n - 1)), n - 1)\n        qc.x(range(n))\n        qc.compose(prep_qc, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A8A4F03D1F0BC", "submission_order": 1, "result": "DLE", "execution_time": "1806 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    split(qc, 0, n)\n\n    return qc\n\ndef split(qc, stIncl, edExcl):\n    if stIncl + 1 == edExcl:\n        return\n\n    mid = (stIncl + edExcl) // 2\n    left = mid - stIncl\n    right = edExcl - mid\n\n    angle = 2*math.atan(math.sqrt(right/left))\n    qc.cry(angle, stIncl, mid)\n    qc.cx(mid, stIncl)\n\n    split(qc, stIncl, mid)\n    split(qc, mid, edExcl)\n\n    return qc\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    return qc\n\ndef refl_psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(psi(n).inverse(), inplace=True)\n    qc.compose(refl(n), inplace=True)\n    qc.compose(psi(n), inplace=True)\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(psi(n), x, inplace=True)\n\n    init_prob = math.sqrt(1/n)\n    init_angle = math.acos(init_prob)\n    target_prob = 0.9\n    repeat = 0\n\n    while True:\n        angle = (2*repeat+1) * init_angle\n        curr_prob = math.cos(angle)**2\n        print(f'{repeat=} {curr_prob=}')\n        if curr_prob > target_prob:\n            break\n\n        qc.compose(o, inplace=True)\n        qc.compose(psi(n).inverse(), inplace=True)\n        qc.compose(refl(n), inplace=True)\n        qc.compose(psi(n), inplace=True)\n\n        repeat += 1\n\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A8A4F03D1F0BC", "submission_order": 2, "result": "WA", "execution_time": "1780 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    split(qc, 0, n)\n\n    return qc\n\ndef split(qc, stIncl, edExcl):\n    if stIncl + 1 == edExcl:\n        return\n\n    mid = (stIncl + edExcl) // 2\n    left = mid - stIncl\n    right = edExcl - mid\n\n    angle = 2*math.atan(math.sqrt(right/left))\n    qc.cry(angle, stIncl, mid)\n    qc.cx(mid, stIncl)\n\n    split(qc, stIncl, mid)\n    split(qc, mid, edExcl)\n\n    return qc\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    return qc\n\ndef refl_psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(psi(n).inverse(), inplace=True)\n    qc.compose(refl(n), inplace=True)\n    qc.compose(psi(n), inplace=True)\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(psi(n), x, inplace=True)\n\n    init_prob = math.sqrt(1/n)\n    init_angle = math.acos(init_prob)\n    target_prob = 0.9\n    repeat = 0\n\n    for _ in range(2):\n        angle = (2*repeat+1) * init_angle\n        curr_prob = math.cos(angle)**2\n        print(f'{repeat=} {curr_prob=}')\n        if curr_prob > target_prob:\n            break\n\n        qc.compose(o, inplace=True)\n        qc.compose(psi(n).inverse(), inplace=True)\n        qc.compose(refl(n), inplace=True)\n        qc.compose(psi(n), inplace=True)\n\n        repeat += 1\n\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A8A4F03D1F0BC", "submission_order": 3, "result": "WA", "execution_time": "1833 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    split(qc, 0, n)\n\n    return qc\n\ndef split(qc, stIncl, edExcl):\n    if stIncl + 1 == edExcl:\n        return\n\n    mid = (stIncl + edExcl) // 2\n    left = mid - stIncl\n    right = edExcl - mid\n\n    angle = 2*math.atan(math.sqrt(right/left))\n    qc.cry(angle, stIncl, mid)\n    qc.cx(mid, stIncl)\n\n    split(qc, stIncl, mid)\n    split(qc, mid, edExcl)\n\n    return qc\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    return qc\n\ndef refl_psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(psi(n).inverse(), inplace=True)\n    qc.compose(refl(n), inplace=True)\n    qc.compose(psi(n), inplace=True)\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    qc.x(y)\n    qc.h(y)\n    qc.compose(psi(n), x, inplace=True)\n\n    init_prob = math.sqrt(1/n)\n    init_angle = math.acos(init_prob)\n    target_prob = 0.9\n    repeat = 0\n\n    for _ in range(3):\n        angle = (2*repeat+1) * init_angle\n        curr_prob = math.cos(angle)**2\n        print(f'{repeat=} {curr_prob=}')\n        if curr_prob > target_prob:\n            break\n\n        qc.compose(o, inplace=True)\n        qc.compose(psi(n).inverse(), inplace=True)\n        qc.compose(refl(n), inplace=True)\n        qc.compose(psi(n), inplace=True)\n\n        repeat += 1\n\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "A8A4F03D1F0BC", "submission_order": 4, "result": "AC", "execution_time": "1988 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    angle = math.acos(1/16)\n    qc.ry(2*math.acos(math.sqrt(1-math.cos(angle)*n)), 0)\n    split(qc, 0, n)\n\n    return qc\n\ndef split(qc, stIncl, edExcl):\n    if stIncl + 1 == edExcl:\n        return\n\n    mid = (stIncl + edExcl) // 2\n    left = mid - stIncl\n    right = edExcl - mid\n\n    angle = 2*math.atan(math.sqrt(right/left))\n    qc.cry(angle, stIncl, mid)\n    qc.cx(mid, stIncl)\n\n    split(qc, stIncl, mid)\n    split(qc, mid, edExcl)\n\n    return qc\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    return qc\n\ndef refl_psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(psi(n).inverse(), inplace=True)\n    qc.compose(refl(n), inplace=True)\n    qc.compose(psi(n), inplace=True)\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.compose(psi(n), x, inplace=True)\n\n    init_prob = math.sqrt(1/16)\n    init_angle = math.acos(init_prob)\n    target_prob = 0.9\n    repeat = 0\n\n    while True:\n        angle = (2*repeat+1) * init_angle\n        curr_prob = math.cos(angle)**2\n        print(f'{repeat=} {curr_prob=}')\n        if curr_prob > target_prob:\n            break\n\n        qc.compose(o, inplace=True)\n        qc.compose(psi(n).inverse(), inplace=True)\n        qc.compose(refl(n), inplace=True)\n        qc.compose(psi(n), inplace=True)\n\n        repeat += 1\n\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AA1618AE47E92", "submission_order": 1, "result": "WA", "execution_time": "1810 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef w_state(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n\n    count = 1\n\n    # queue = [(a, b, control bit of CRy), ...]\n    queue = [(n // 2, n, 0)]\n\n    # breadth first search\n    while len(queue):\n        a, b, control = queue.pop(0)\n\n        if a == 0:\n            continue\n\n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n\n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n\n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n\n        count += 1\n\n    return qc\n\ndef reflect_w_state(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(w_state(n).inverse(), inplace=True)\n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n    qc.compose(w_state(n), inplace=True)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = math.asin(1 / (n) ** 0.5)\n    iterations = math.floor(math.pi / (4 * theta))\n    # print(theta, iterations)\n    qc.compose(w_state(n), inplace=True)\n    reflect = reflect_w_state(n)\n    for _ in range(iterations):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o.inverse(), inplace=True)\n        qc.compose(reflect, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AA1618AE47E92", "submission_order": 2, "result": "WA", "execution_time": "1827 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\n\ndef w_state(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n\n    count = 1\n\n    # queue = [(a, b, control bit of CRy), ...]\n    queue = [(n // 2, n, 0)]\n\n    # breadth first search\n    while len(queue):\n        a, b, control = queue.pop(0)\n\n        if a == 0:\n            continue\n\n        theta = 2 * math.atan(math.sqrt((b - a) / a))\n\n        qc.cry(theta, control, count)\n        qc.cx(count, control)\n\n        queue.append(((b // 2) // 2, b // 2, control))\n        queue.append((math.ceil(b / 2) // 2, math.ceil(b / 2), count))\n\n        count += 1\n\n    return qc\n\ndef reflect_w_state(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(w_state(n).inverse(), inplace=True)\n    qc.x(range(n))\n    qc.append(ZGate().control(n - 1), range(n))\n    qc.x(range(n))\n    qc.compose(w_state(n), inplace=True)\n    return qc\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n\n    theta = math.asin(1 / n ** 0.5)\n    iterations = math.floor(math.pi / (4 * theta))\n    # print(f\"{theta = } {iterations = }\")\n    qc.compose(w_state(n), inplace=True)\n    reflect = reflect_w_state(n)\n    for _ in range(iterations):\n        qc.compose(o, inplace=True)\n        qc.z(y)\n        qc.compose(o.inverse(), inplace=True)\n        qc.compose(reflect, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AA88D013A27C7", "submission_order": 1, "result": "RE", "execution_time": "1647 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qr = QuantumRegister(n, 'q')\n    anc = QuantumRegister(1, 'ancilla')\n    qc = QuantumCircuit(qr, anc)\n    \n    qc.h(qr)\n    \n    qc.x(anc)\n    qc.h(anc)\n    \n    qc.compose(o, qubits=qr[:] + anc[:], inplace=True)\n    \n    qc.h(qr)\n    qc.x(qr)\n    qc.h(qr[-1])\n    qc.mct(qr[:-1], qr[-1])\n    qc.h(qr[-1])\n    qc.x(qr)\n    qc.h(qr)\n    \n    qc = qc.remove_final_measurements(inplace=False)\n    \n    final_qc = QuantumCircuit(n)\n    final_qc.compose(qc, qubits=range(n), inplace=True)\n    \n    return final_qc\n'''"}
{"problem": "QPC003_EX2", "user": "AA88D013A27C7", "submission_order": 2, "result": "RE", "execution_time": "1624 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    ancilla = n - 1  \n    qc.x(ancilla)\n    qc.h(ancilla)\n    \n    qc.h(range(n-1))\n    qc.compose(o, inplace=True)\n    \n    qc.h(range(n-1))\n    qc.x(range(n-1))\n    qc.mct(list(range(n-1)), ancilla)  \n    qc.x(range(n-1))\n    qc.h(range(n-1))\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AA88D013A27C7", "submission_order": 3, "result": "RE", "execution_time": "1357 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(range(n))\n    \n    qc.compose(o, inplace=True)\n    \n    qc.h(range(n))\n    qc.x(range(n))\n    qc.mcz(list(range(n-1)), n-1)  \n    qc.x(range(n))\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AA88D013A27C7", "submission_order": 4, "result": "WA", "execution_time": "1524 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    k = 75 // (2*n+4)\n    for _ in range(k):\n        qc.compose(o, inplace=True)\n        qc.h(range(n))\n        qc.x(range(n))\n        qc.h(n-1)\n        qc.mcx(list(range(n-1)), n-1)\n        qc.h(n-1)\n        qc.x(range(n))\n        qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AAB48AE0D5F9E", "submission_order": 1, "result": "RE", "execution_time": "1124 ms", "memory": "152 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate, ZGate, RYGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef a5(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    if n==7:\n        qc.ry(math.asin(-1/math.sqrt(n+1))*2, 0)\n        for i in range(1, n):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i+1))*2).control(i), range(i+1))\n        # qc.mcx(list(range(n-1)), n-1)\n    else:\n        qc.ry(math.asin(-1/math.sqrt(n))*2, 0)\n        for i in range(1, n-1):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i))*2).control(i), range(i+1))\n        qc.mcx(list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n    return qc\n\n\ndef b7(n: int, T: list[float]) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(a5(n, T).inverse(), inplace=True)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1), list(range(n)))\n    for i in range(n):\n        qc.x(i)\n    # qc.append(GlobalPhaseGate(math.pi))\n    qc.compose(a5(n, T), inplace=True)\n    return qc\n\n# def b5(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     # init = [0]*(2**n)\n#     # init[2] = 1\n#     # qc.initialize(init)\n#     # Write your code here:\n#     for i in range(n):\n#         qc.h(i)\n#     for i in range(n):\n#         qc.x(i)\n#     qc.append(ZGate().control(n-1), list(range(n)))\n#     for i in range(n):\n#         qc.x(i)\n#     for i in range(n):\n#         qc.h(i)\n#     return qc\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(a5(n), inplace=True)\n    \n    t = math.asin(1/math.sqrt(n))\n    for i in range(1, 100):\n        qc.compose(o, inplace=True)\n        qc.compose(b7(n), inplace=True)\n        if math.sin((2*i+1)*t)**2>=0.9:\n            break\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AAB48AE0D5F9E", "submission_order": 2, "result": "DLE", "execution_time": "1260 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate, ZGate, RYGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef a5(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    if n==7:\n        qc.ry(math.asin(-1/math.sqrt(n+1))*2, 0)\n        for i in range(1, n):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i+1))*2).control(i), range(i+1))\n        # qc.mcx(list(range(n-1)), n-1)\n    else:\n        qc.ry(math.asin(-1/math.sqrt(n))*2, 0)\n        for i in range(1, n-1):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i))*2).control(i), range(i+1))\n        qc.mcx(list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n    return qc\n\n\ndef b7(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(a5(n).inverse(), inplace=True)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1), list(range(n)))\n    for i in range(n):\n        qc.x(i)\n    # qc.append(GlobalPhaseGate(math.pi))\n    qc.compose(a5(n), inplace=True)\n    return qc\n\n# def b5(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     # init = [0]*(2**n)\n#     # init[2] = 1\n#     # qc.initialize(init)\n#     # Write your code here:\n#     for i in range(n):\n#         qc.h(i)\n#     for i in range(n):\n#         qc.x(i)\n#     qc.append(ZGate().control(n-1), list(range(n)))\n#     for i in range(n):\n#         qc.x(i)\n#     for i in range(n):\n#         qc.h(i)\n#     return qc\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(a5(n), inplace=True)\n\n    t = math.asin(1/math.sqrt(n))\n    for i in range(1, 100):\n        qc.compose(o, inplace=True)\n        qc.compose(b7(n), inplace=True)\n        if math.sin((2*i+1)*t)**2>=0.9:\n            break\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AAB48AE0D5F9E", "submission_order": 3, "result": "DLE", "execution_time": "1350 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate, ZGate, RYGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef a5(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    if n==7:\n        qc.ry(math.asin(-1/math.sqrt(n+1))*2, 0)\n        for i in range(1, n):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i+1))*2).control(i), range(i+1))\n        # qc.mcx(list(range(n-1)), n-1)\n    else:\n        qc.ry(math.asin(-1/math.sqrt(n))*2, 0)\n        for i in range(1, n-1):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i))*2).control(i), range(i+1))\n        qc.mcx(list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n    return qc\n\n\ndef b7(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(a5(n).inverse(), inplace=True)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1), list(range(n)))\n    for i in range(n):\n        qc.x(i)\n    # qc.append(GlobalPhaseGate(math.pi))\n    qc.compose(a5(n), inplace=True)\n    return qc\n\n# def b5(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     # init = [0]*(2**n)\n#     # init[2] = 1\n#     # qc.initialize(init)\n#     # Write your code here:\n#     for i in range(n):\n#         qc.h(i)\n#     for i in range(n):\n#         qc.x(i)\n#     qc.append(ZGate().control(n-1), list(range(n)))\n#     for i in range(n):\n#         qc.x(i)\n#     for i in range(n):\n#         qc.h(i)\n#     return qc\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(a5(n), inplace=True)\n\n    t = math.asin(1/math.sqrt(n))\n    if n==7:\n        t = math.asin(1/math.sqrt(n+1))\n    for i in range(1, 100):\n        qc.compose(o, inplace=True)\n        qc.compose(b7(n), inplace=True)\n        if math.sin((2*i+1)*t)**2>=0.9:\n            break\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AAB48AE0D5F9E", "submission_order": 4, "result": "RE", "execution_time": "1296 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate, ZGate, RYGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef a5(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    if n==7:\n        qc.ry(math.asin(-1/math.sqrt(n+1))*2, 0)\n        for i in range(1, n):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i+1))*2).control(i), range(i+1))\n        # qc.mcx(list(range(n-1)), n-1)\n    else:\n        qc.ry(math.asin(-1/math.sqrt(n))*2, 0)\n        for i in range(1, n-1):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i))*2).control(i), range(i+1))\n        qc.mcx(list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n    return qc\n\n\ndef b7(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(a5(n).inverse(), inplace=True)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1), list(range(n)))\n    for i in range(n):\n        qc.x(i)\n    # qc.append(GlobalPhaseGate(math.pi))\n    qc.compose(a5(n), inplace=True)\n    return qc\n\n# def b5(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     # init = [0]*(2**n)\n#     # init[2] = 1\n#     # qc.initialize(init)\n#     # Write your code here:\n#     for i in range(n):\n#         qc.h(i)\n#     for i in range(n):\n#         qc.x(i)\n#     qc.append(ZGate().control(n-1), list(range(n)))\n#     for i in range(n):\n#         qc.x(i)\n#     for i in range(n):\n#         qc.h(i)\n#     return qc\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    assert n!=10\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(a5(n), inplace=True)\n\n    t = math.asin(1/math.sqrt(n))\n    if n==7:\n        t = math.asin(1/math.sqrt(n+1))\n    for i in range(1, 100):\n        qc.compose(o, inplace=True)\n        qc.compose(b7(n), inplace=True)\n        if math.sin((2*i+1)*t)**2>=0.9:\n            break\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AAB48AE0D5F9E", "submission_order": 5, "result": "AC", "execution_time": "2966 ms", "memory": "173 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import GlobalPhaseGate, ZGate, RYGate\nimport math\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef a5(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    if n==7 or n==2:\n        qc.ry(math.asin(-1/math.sqrt(n+1))*2, 0)\n        for i in range(1, n):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i+1))*2).control(i), range(i+1))\n        # qc.mcx(list(range(n-1)), n-1)\n    else:\n        qc.ry(math.asin(-1/math.sqrt(n))*2, 0)\n        for i in range(1, n-1):\n            qc.append(RYGate(math.asin(-1/math.sqrt(n-i))*2).control(i), range(i+1))\n        qc.mcx(list(range(n-1)), n-1)\n\n    for i in range(n):\n        qc.x(i)\n    return qc\n\n\ndef b7(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.compose(a5(n).inverse(), inplace=True)\n    for i in range(n):\n        qc.x(i)\n    qc.append(ZGate().control(n-1), list(range(n)))\n    for i in range(n):\n        qc.x(i)\n    # qc.append(GlobalPhaseGate(math.pi))\n    qc.compose(a5(n), inplace=True)\n    return qc\n\n# def b5(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     # init = [0]*(2**n)\n#     # init[2] = 1\n#     # qc.initialize(init)\n#     # Write your code here:\n#     for i in range(n):\n#         qc.h(i)\n#     for i in range(n):\n#         qc.x(i)\n#     qc.append(ZGate().control(n-1), list(range(n)))\n#     for i in range(n):\n#         qc.x(i)\n#     for i in range(n):\n#         qc.h(i)\n#     return qc\n \ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(a5(n), inplace=True)\n\n    t = math.asin(1/math.sqrt(n))\n    if n==7 or n==2:\n        t = math.asin(1/math.sqrt(n+1))\n    for i in range(1, 100):\n        qc.compose(o, inplace=True)\n        qc.compose(b7(n), inplace=True)\n        if math.sin((2*i+1)*t)**2>=0.9:\n            break\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AD248C13D2A2D", "submission_order": 1, "result": "RE", "execution_time": "1394 ms", "memory": "154 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.append(HGate(), [i])  \n\n    qc.compose(o, inplace=True)\n\n    for i in range(n):\n        qc.append(HGate(), [i])\n        \n    for i in range(n):\n        qc.append(XGate(), [i])\n        \n    qc.h(n-1)\n    qc.mct(list(range(n-1)), n-1)  \n    qc.h(n-1)\n    \n    for i in range(n):\n        qc.append(XGate(), [i])\n\n    for i in range(n):\n        qc.append(HGate(), [i])\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AD9EE9692F48F", "submission_order": 1, "result": "RE", "execution_time": "2267 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.y(0)\n\n    return qc\n'''"}
{"problem": "QPC003_EX2", "user": "AD9EE9692F48F", "submission_order": 2, "result": "AC", "execution_time": "2518 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, GlobalPhaseGate\nimport numpy as np\nimport math\n\ndef psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    angle = math.acos(1/16)\n    qc.ry(2*math.acos(math.sqrt(1-math.cos(angle)*n)), 0)\n    split(qc, 0, n)\n\n    return qc\n\ndef split(qc, stIncl, edExcl):\n    if stIncl + 1 == edExcl:\n        return\n\n    mid = (stIncl + edExcl) // 2\n    left = mid - stIncl\n    right = edExcl - mid\n\n    angle = 2*math.atan(math.sqrt(right/left))\n    qc.cry(angle, stIncl, mid)\n    qc.cx(mid, stIncl)\n\n    split(qc, stIncl, mid)\n    split(qc, mid, edExcl)\n\n    return qc\n\ndef refl(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.append(GlobalPhaseGate(math.pi))\n    qc.x(range(n))\n\n    mcz = ZGate().control(n-1)\n    qc.append(mcz, list(range(n)))\n\n    qc.x(range(n))\n\n    return qc\n\ndef refl_psi(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.compose(psi(n).inverse(), inplace=True)\n    qc.compose(refl(n), inplace=True)\n    qc.compose(psi(n), inplace=True)\n    return qc\n\ndef solve(n: int, o: QuantumCircuit) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.x(y)\n    qc.h(y)\n    qc.compose(psi(n), x, inplace=True)\n\n    init_prob = math.sqrt(1/16)\n    init_angle = math.acos(init_prob)\n    target_prob = 0.9\n    repeat = 0\n\n    while True:\n        angle = (2*repeat+1) * init_angle\n        curr_prob = math.cos(angle)**2\n        print(f'{repeat=} {curr_prob=}')\n        if curr_prob > target_prob:\n            break\n\n        qc.compose(o, inplace=True)\n        qc.compose(psi(n).inverse(), inplace=True)\n        qc.compose(refl(n), inplace=True)\n        qc.compose(psi(n), inplace=True)\n\n        repeat += 1\n\n    qc.h(y)\n    qc.x(y)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A00C73306AD07", "submission_order": 1, "result": "AC", "execution_time": "2104 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A01648FFFDB21", "submission_order": 1, "result": "AC", "execution_time": "1785 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A0196A070FEF8", "submission_order": 1, "result": "AC", "execution_time": "1706 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A025B0682BA02", "submission_order": 1, "result": "AC", "execution_time": "1931 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A0285E7EA6A24", "submission_order": 1, "result": "AC", "execution_time": "1709 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A033ED9692939", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(₁)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A033ED9692939", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(₀)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A033ED9692939", "submission_order": 3, "result": "AC", "execution_time": "1752 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A0382E8F23E87", "submission_order": 1, "result": "AC", "execution_time": "1857 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A05E92625EF2F", "submission_order": 1, "result": "AC", "execution_time": "1628 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A064F7AC9CC7F", "submission_order": 1, "result": "AC", "execution_time": "2102 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A0AB4CB2203DC", "submission_order": 1, "result": "AC", "execution_time": "2846 ms", "memory": "202 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    for _ in range(2*10**4+1):\n        qc.x(0)\n\n    return qc\n\n\n# from qiskit import Aer, execute\n\n# def simulate(qc: QuantumCircuit):\n#     simulator = Aer.get_backend(\"statevector_simulator\")\n#     statevector = execute(qc, simulator).result().get_statevector(qc)\n#     print(statevector)\n \n \n# if __name__ == \"__main__\":\n#     simulate(solve())\n'''"}
{"problem": "QPC004_A1", "user": "A0CC2D9C0910B", "submission_order": 1, "result": "AC", "execution_time": "2204 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A0E5DE34010D7", "submission_order": 1, "result": "AC", "execution_time": "1775 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A0E9C5E28285D", "submission_order": 1, "result": "AC", "execution_time": "1935 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A11F82D38A336", "submission_order": 1, "result": "AC", "execution_time": "1705 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A129DACCBF2C2", "submission_order": 1, "result": "AC", "execution_time": "1895 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A146806CA08F5", "submission_order": 1, "result": "AC", "execution_time": "1683 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A1BBBFE1C0F13", "submission_order": 1, "result": "RE", "execution_time": "2648 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    c.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A1BBBFE1C0F13", "submission_order": 2, "result": "AC", "execution_time": "2819 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A1D7F23CB680F", "submission_order": 1, "result": "AC", "execution_time": "1749 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A1F591408DAC5", "submission_order": 1, "result": "AC", "execution_time": "1807 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A2183BA6E7892", "submission_order": 1, "result": "AC", "execution_time": "1724 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A22DC59D8EF6D", "submission_order": 1, "result": "AC", "execution_time": "1897 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A23105CDE06A7", "submission_order": 1, "result": "AC", "execution_time": "1975 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A2F43814ABD62", "submission_order": 1, "result": "AC", "execution_time": "1844 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A32AD6898FA0D", "submission_order": 1, "result": "AC", "execution_time": "1843 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A33A19B2A837A", "submission_order": 1, "result": "AC", "execution_time": "1595 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A3CFB2E7A539D", "submission_order": 1, "result": "AC", "execution_time": "2497 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A3F5A331DBF10", "submission_order": 1, "result": "AC", "execution_time": "1718 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4102FFD7590A", "submission_order": 1, "result": "AC", "execution_time": "2219 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A44B62C717E5B", "submission_order": 1, "result": "RE", "execution_time": "1595 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x();\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A44B62C717E5B", "submission_order": 2, "result": "AC", "execution_time": "1786 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0);\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4599A9AA67FC", "submission_order": 1, "result": "AC", "execution_time": "1934 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A48B2454A0DC7", "submission_order": 1, "result": "RE", "execution_time": "1776 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A48B2454A0DC7", "submission_order": 2, "result": "WA", "execution_time": "1945 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A48B2454A0DC7", "submission_order": 3, "result": "AC", "execution_time": "1698 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4AD1D5450403", "submission_order": 1, "result": "RE", "execution_time": "1650 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4AD1D5450403", "submission_order": 2, "result": "AC", "execution_time": "1661 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4B528455FF08", "submission_order": 1, "result": "WA", "execution_time": "2089 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4B9ABD33113B", "submission_order": 1, "result": "AC", "execution_time": "1916 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4C7EAAB11C5E", "submission_order": 1, "result": "AC", "execution_time": "1906 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4EEE334225EF", "submission_order": 1, "result": "AC", "execution_time": "1727 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A4FF02C22EF2B", "submission_order": 1, "result": "AC", "execution_time": "1738 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    # Create quantum circuit with 1 qubit\n    qc = QuantumCircuit(1)\n    \n    # Apply X gate to flip from |0⟩ to |1⟩\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A50475A958D97", "submission_order": 1, "result": "AC", "execution_time": "1602 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A51A825C5A8FF", "submission_order": 1, "result": "AC", "execution_time": "1849 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A51B8E08A0A6F", "submission_order": 1, "result": "WA", "execution_time": "1701 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A58213E246CBA", "submission_order": 1, "result": "AC", "execution_time": "1884 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A5F8C835EDB4A", "submission_order": 1, "result": "AC", "execution_time": "2451 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A61AB1088077A", "submission_order": 1, "result": "AC", "execution_time": "1792 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A626190674A7B", "submission_order": 1, "result": "AC", "execution_time": "1943 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A68D09F02C723", "submission_order": 1, "result": "AC", "execution_time": "1867 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A6B5799580F14", "submission_order": 1, "result": "AC", "execution_time": "1837 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A6D4ACDCACA6D", "submission_order": 1, "result": "RE", "execution_time": "1928 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.c(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A6D4ACDCACA6D", "submission_order": 2, "result": "RE", "execution_time": "1853 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.xc(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A6D4ACDCACA6D", "submission_order": 3, "result": "AC", "execution_time": "1814 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A6D9D55D4D1F0", "submission_order": 1, "result": "AC", "execution_time": "1969 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A6F143F68D1E5", "submission_order": 1, "result": "AC", "execution_time": "1486 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A71B2940ED959", "submission_order": 1, "result": "AC", "execution_time": "2005 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A74AB8D0BD278", "submission_order": 1, "result": "AC", "execution_time": "1684 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A7B816EA485C8", "submission_order": 1, "result": "RE", "execution_time": "1405 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc=qc.x(qc)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A7B816EA485C8", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A7E0342F6C019", "submission_order": 1, "result": "AC", "execution_time": "2174 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A7EA102AB387B", "submission_order": 1, "result": "AC", "execution_time": "1662 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A8223B9BB50EF", "submission_order": 1, "result": "RE", "execution_time": "1636 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.X(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A8223B9BB50EF", "submission_order": 2, "result": "AC", "execution_time": "1726 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A858117FBCFA3", "submission_order": 1, "result": "AC", "execution_time": "1727 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A86C69B87943D", "submission_order": 1, "result": "WA", "execution_time": "1660 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A86C69B87943D", "submission_order": 2, "result": "AC", "execution_time": "1759 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A879B426A0DD7", "submission_order": 1, "result": "WA", "execution_time": "1846 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A87D148EEAC39", "submission_order": 1, "result": "AC", "execution_time": "1888 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A880973246450", "submission_order": 1, "result": "AC", "execution_time": "1887 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A882B22A7B016", "submission_order": 1, "result": "AC", "execution_time": "1902 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A885F6A2B5926", "submission_order": 1, "result": "AC", "execution_time": "1566 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A890C8FD96156", "submission_order": 1, "result": "AC", "execution_time": "1919 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A8B49D54C350D", "submission_order": 1, "result": "AC", "execution_time": "1698 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A8BD236223F23", "submission_order": 1, "result": "AC", "execution_time": "1873 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A904DBE02A3DC", "submission_order": 1, "result": "AC", "execution_time": "1613 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A93563E5D7D1B", "submission_order": 1, "result": "AC", "execution_time": "1827 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A94D1BEBD9965", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\nqc.g(i)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A94D1BEBD9965", "submission_order": 2, "result": "RE", "execution_time": "1807 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A94D1BEBD9965", "submission_order": 3, "result": "RE", "execution_time": "1754 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A9777A34215E0", "submission_order": 1, "result": "AC", "execution_time": "2010 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Apply the Pauli-X gate to flip the state from |0> to |1>\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A98C7DF93CF24", "submission_order": 1, "result": "AC", "execution_time": "1943 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A9A6FA4AE0373", "submission_order": 1, "result": "RE", "execution_time": "1804 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A9A6FA4AE0373", "submission_order": 2, "result": "RE", "execution_time": "1538 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.g(1)\n    qc.data\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "A9BC2EEF6632B", "submission_order": 1, "result": "AC", "execution_time": "1723 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AA0251A67487F", "submission_order": 1, "result": "AC", "execution_time": "1854 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    # Write your code here:\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AA4318B04D535", "submission_order": 1, "result": "RE", "execution_time": "1556 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(1)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AA4318B04D535", "submission_order": 2, "result": "RE", "execution_time": "1548 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AA4318B04D535", "submission_order": 3, "result": "AC", "execution_time": "1754 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AA59C2AD7CAB1", "submission_order": 1, "result": "AC", "execution_time": "1755 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AABCAE77B5556", "submission_order": 1, "result": "AC", "execution_time": "1905 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AADF1B66122F1", "submission_order": 1, "result": "AC", "execution_time": "1775 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AAE5A595F9AB8", "submission_order": 1, "result": "AC", "execution_time": "1835 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB276D6C9B7BB", "submission_order": 1, "result": "AC", "execution_time": "1791 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB3C080660038", "submission_order": 1, "result": "WA", "execution_time": "2094 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB3C080660038", "submission_order": 2, "result": "AC", "execution_time": "1785 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB63B48106AB3", "submission_order": 1, "result": "AC", "execution_time": "1710 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB6DFE93A4924", "submission_order": 1, "result": "RE", "execution_time": "1781 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(XGate())\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB6DFE93A4924", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, XGate\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.append(XGate())\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB6DFE93A4924", "submission_order": 3, "result": "AC", "execution_time": "1745 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB7D31BEDB308", "submission_order": 1, "result": "RE", "execution_time": "1687 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB7D31BEDB308", "submission_order": 2, "result": "AC", "execution_time": "1793 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AB82AFA82FD71", "submission_order": 1, "result": "AC", "execution_time": "2456 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ABC282B68FD57", "submission_order": 1, "result": "AC", "execution_time": "2046 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ABCD752264093", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ABE9188ADBFF6", "submission_order": 1, "result": "AC", "execution_time": "1945 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AC0FC313DE6F5", "submission_order": 1, "result": "AC", "execution_time": "1920 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AC53ABCBBF072", "submission_order": 1, "result": "AC", "execution_time": "1966 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AC6F2DA6548C8", "submission_order": 1, "result": "AC", "execution_time": "1856 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ACB2471802699", "submission_order": 1, "result": "AC", "execution_time": "2693 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ACF6A6EB2482D", "submission_order": 1, "result": "RE", "execution_time": "1684 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ACF6A6EB2482D", "submission_order": 2, "result": "AC", "execution_time": "1802 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AD075C43C2B49", "submission_order": 1, "result": "AC", "execution_time": "1827 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AD384EB15C522", "submission_order": 1, "result": "RE", "execution_time": "1711 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\ncircuit = QuantumCircuit(2)\ncircuit.h(0)\ncircuit.cx(0, 1)\ncircuit.ry(-3. * np.pi / 4., 1)\n\ncircuit.draw('mpl')\n'''"}
{"problem": "QPC004_A1", "user": "AD5A47D2BBEEA", "submission_order": 1, "result": "AC", "execution_time": "1736 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ADA35527728A3", "submission_order": 1, "result": "RE", "execution_time": "1740 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ADA35527728A3", "submission_order": 2, "result": "AC", "execution_time": "1936 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ADC5F7A4A5241", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ADC70668DA2B8", "submission_order": 1, "result": "AC", "execution_time": "1876 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "ADDC30BA227B9", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n \n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC004_A1", "user": "ADDC30BA227B9", "submission_order": 2, "result": "AC", "execution_time": "1480 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_A1", "user": "ADF8469DBB04F", "submission_order": 1, "result": "AC", "execution_time": "2005 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # 量子ビット0番にXゲートを適用\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AE2BA7E4DE6D8", "submission_order": 1, "result": "AC", "execution_time": "2069 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:]\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AE4D7D2903318", "submission_order": 1, "result": "AC", "execution_time": "2986 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AE6E96F778BE6", "submission_order": 1, "result": "AC", "execution_time": "1667 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AE8103546531F", "submission_order": 1, "result": "AC", "execution_time": "1832 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(1)\n\tqc.x(0)\n\treturn qc\n'''"}
{"problem": "QPC004_A1", "user": "AE9406A5C47B1", "submission_order": 1, "result": "AC", "execution_time": "1929 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AF107143E3209", "submission_order": 1, "result": "AC", "execution_time": "1879 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A1", "user": "AFC9030CB783C", "submission_order": 1, "result": "AC", "execution_time": "2977 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A03974F816A8C", "submission_order": 1, "result": "UGE", "execution_time": "1847 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A03974F816A8C", "submission_order": 2, "result": "AC", "execution_time": "2081 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A04003BFF4298", "submission_order": 1, "result": "AC", "execution_time": "2276 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A076516AB56A3", "submission_order": 1, "result": "WA", "execution_time": "1576 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A0F734E0F66B9", "submission_order": 1, "result": "WA", "execution_time": "2429 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A0F734E0F66B9", "submission_order": 2, "result": "WA", "execution_time": "1696 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0,1)\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A0F734E0F66B9", "submission_order": 3, "result": "WA", "execution_time": "1719 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    \n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A0F734E0F66B9", "submission_order": 4, "result": "WA", "execution_time": "1687 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.x(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A0F734E0F66B9", "submission_order": 5, "result": "WA", "execution_time": "1793 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(0)\n    qc.cx(0,1)\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A0F734E0F66B9", "submission_order": 6, "result": "WA", "execution_time": "1947 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.h(0)\n    qc.h(1)\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A0F734E0F66B9", "submission_order": 7, "result": "AC", "execution_time": "1927 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    \n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A10034DF9AF3D", "submission_order": 1, "result": "AC", "execution_time": "2015 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A10DA2A20B9BF", "submission_order": 1, "result": "AC", "execution_time": "2065 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: CNOT from qubit 0 to qubit 1\n    qc.cx(0, 1)\n    \n    # Step 2: CNOT from qubit 1 to qubit 0\n    qc.cx(1, 0)\n    \n    # Step 3: CNOT from qubit 0 to qubit 1 again\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A11157AFAA31C", "submission_order": 1, "result": "WA", "execution_time": "1662 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A11157AFAA31C", "submission_order": 2, "result": "AC", "execution_time": "2512 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A124BD5921B9F", "submission_order": 1, "result": "UGE", "execution_time": "1837 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A124BD5921B9F", "submission_order": 2, "result": "AC", "execution_time": "1737 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A17144158904C", "submission_order": 1, "result": "AC", "execution_time": "2375 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A19C5BACC9B1D", "submission_order": 1, "result": "AC", "execution_time": "2316 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A204AAE271DB5", "submission_order": 1, "result": "AC", "execution_time": "2473 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A2240720BE0FD", "submission_order": 1, "result": "AC", "execution_time": "1923 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A230E5892E649", "submission_order": 1, "result": "WA", "execution_time": "2072 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A230E5892E649", "submission_order": 2, "result": "WA", "execution_time": "1884 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    # Apply X gates to initialize qubits\n    qc.x(0)\n    qc.x(1)\n    \n    # Implement SWAP using CX gates\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A230E5892E649", "submission_order": 3, "result": "AC", "execution_time": "2009 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    # Implement SWAP using CX gates\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A2456C9223BAD", "submission_order": 1, "result": "AC", "execution_time": "1641 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A24C2261A60E5", "submission_order": 1, "result": "AC", "execution_time": "1900 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A276387D9CDBB", "submission_order": 1, "result": "AC", "execution_time": "2102 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A2B12BF3FD458", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A2B12BF3FD458", "submission_order": 2, "result": "AC", "execution_time": "1847 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A2EEEB96E2696", "submission_order": 1, "result": "AC", "execution_time": "2310 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    qc.cx(0, 1)\n    qc.cx(0, 1)\n\n    #     qc.cx(0, 1)\n    # qc.cx(1, 0)\n    # qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A321BBC833B0C", "submission_order": 1, "result": "UGE", "execution_time": "2139 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library import GlobalPhaseGate\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A321BBC833B0C", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A32F29C27CD57", "submission_order": 1, "result": "AC", "execution_time": "2386 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A334ADEC978CA", "submission_order": 1, "result": "AC", "execution_time": "2268 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A3934B4A01D1F", "submission_order": 1, "result": "UGE", "execution_time": "1551 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A3934B4A01D1F", "submission_order": 2, "result": "UGE", "execution_time": "1897 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A3934B4A01D1F", "submission_order": 3, "result": "AC", "execution_time": "1879 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A4017A5F0D41F", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nimport numpy as np\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # For debugging\n    # initial_state = [1/np.sqrt(2),0,  1/np.sqrt(2),0]\n    # qc.initialize(initial_state, [0, 1])\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC004_A2", "user": "A4017A5F0D41F", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n# import numpy as np\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # For debugging\n    # initial_state = [1/np.sqrt(2),0,  1/np.sqrt(2),0]\n    # qc.initialize(initial_state, [0, 1])\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n\nif __name__ == \"__main__\":\n    qc = solve()\n    print(Statevector(qc))\n'''"}
{"problem": "QPC004_A2", "user": "A4017A5F0D41F", "submission_order": 3, "result": "AC", "execution_time": "2253 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A442641092271", "submission_order": 1, "result": "UGE", "execution_time": "1920 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A442641092271", "submission_order": 2, "result": "AC", "execution_time": "2087 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A456F03ECF2E2", "submission_order": 1, "result": "AC", "execution_time": "1926 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A4AD362F23BC6", "submission_order": 1, "result": "AC", "execution_time": "1781 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    \n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)    \n \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A4BEAAE27140F", "submission_order": 1, "result": "AC", "execution_time": "2447 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    # Create quantum circuit with 2 qubits\n    qc = QuantumCircuit(2)\n    \n    # Implement SWAP using 3 CNOT gates\n    qc.cx(0, 1)  # First CNOT\n    qc.cx(1, 0)  # Second CNOT\n    qc.cx(0, 1)  # Third CNOT\n    \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A4D692B4A684D", "submission_order": 1, "result": "UGE", "execution_time": "2004 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A4D692B4A684D", "submission_order": 2, "result": "AC", "execution_time": "2396 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A4F992E40BC58", "submission_order": 1, "result": "AC", "execution_time": "1929 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A51433FE92572", "submission_order": 1, "result": "UGE", "execution_time": "1917 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A51433FE92572", "submission_order": 2, "result": "AC", "execution_time": "2693 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A514C7769546A", "submission_order": 1, "result": "UGE", "execution_time": "2053 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A514C7769546A", "submission_order": 2, "result": "WA", "execution_time": "2352 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.iswap(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A514C7769546A", "submission_order": 3, "result": "RE", "execution_time": "2020 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.iswap(0,1)\n    qc.p(0)\n    qc.z(0)\n    qc.p(1)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A514C7769546A", "submission_order": 4, "result": "WA", "execution_time": "2030 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.iswap(0,1)\n    qc.p(3*pi/2, 0)\n    qc.p(3*pi/2, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A514C7769546A", "submission_order": 5, "result": "WA", "execution_time": "2123 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.iswap(0,1)\n    qc.p(3*pi/2, 0)\n    qc.p(3*pi/2, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A514C7769546A", "submission_order": 6, "result": "AC", "execution_time": "2193 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.iswap(0,1)\n    qc.p(3*pi/2, 0)\n    qc.p(3*pi/2, 1)\n    qc.cz(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A5B2D36C0840A", "submission_order": 1, "result": "AC", "execution_time": "1874 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A5BE7DEE9508D", "submission_order": 1, "result": "AC", "execution_time": "2616 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A5DEAC9D09F7B", "submission_order": 1, "result": "AC", "execution_time": "2459 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A69648039BF32", "submission_order": 1, "result": "AC", "execution_time": "2192 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A69894EDA1A55", "submission_order": 1, "result": "RE", "execution_time": "1981 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A69894EDA1A55", "submission_order": 2, "result": "RE", "execution_time": "1545 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A69894EDA1A55", "submission_order": 3, "result": "AC", "execution_time": "1835 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A69C4892FE996", "submission_order": 1, "result": "AC", "execution_time": "2269 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A6B73DE4D4406", "submission_order": 1, "result": "RE", "execution_time": "1841 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cnot(0,1)\n    qc.cnot(1,0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A6B73DE4D4406", "submission_order": 2, "result": "RE", "execution_time": "1563 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cnot(0,1)\n    qc.cnot(1,0)\n    qc.cnot(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A6B73DE4D4406", "submission_order": 3, "result": "AC", "execution_time": "2483 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A6CFAA6726948", "submission_order": 1, "result": "AC", "execution_time": "2030 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A6DDABDFD758D", "submission_order": 1, "result": "AC", "execution_time": "1746 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    # qc.x(0)\n    \n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_A2", "user": "A6F1F6E953191", "submission_order": 1, "result": "AC", "execution_time": "2923 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A7161BF061AFB", "submission_order": 1, "result": "AC", "execution_time": "2057 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A742BE25F006C", "submission_order": 1, "result": "AC", "execution_time": "1943 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A79F2B9A6ACD8", "submission_order": 1, "result": "AC", "execution_time": "1894 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A807905A09E82", "submission_order": 1, "result": "AC", "execution_time": "1923 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A8316108EE34E", "submission_order": 1, "result": "AC", "execution_time": "2201 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A84002FC66F49", "submission_order": 1, "result": "AC", "execution_time": "2808 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A857B9D255D17", "submission_order": 1, "result": "AC", "execution_time": "1936 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A8666E6218611", "submission_order": 1, "result": "UGE", "execution_time": "1582 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A8666E6218611", "submission_order": 2, "result": "AC", "execution_time": "2176 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A86B15D042CA1", "submission_order": 1, "result": "AC", "execution_time": "1672 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A86C4BFE0A8B3", "submission_order": 1, "result": "AC", "execution_time": "1803 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A87B8D7E06A3D", "submission_order": 1, "result": "AC", "execution_time": "2043 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A884BAD200FD0", "submission_order": 1, "result": "AC", "execution_time": "2657 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A8D0B3973D498", "submission_order": 1, "result": "AC", "execution_time": "2040 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A8D23399B9DF1", "submission_order": 1, "result": "RE", "execution_time": "1917 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0,2)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A8D23399B9DF1", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "153 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A8D23399B9DF1", "submission_order": 3, "result": "AC", "execution_time": "2281 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A91B72656138F", "submission_order": 1, "result": "AC", "execution_time": "2005 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A96FFBE4EE7F1", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A9C747014CBDA", "submission_order": 1, "result": "AC", "execution_time": "2477 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A9D14B1570B3B", "submission_order": 1, "result": "AC", "execution_time": "2416 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "A9E1F7BBD305A", "submission_order": 1, "result": "AC", "execution_time": "2145 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # 以下三次 CNOT 就可实现 SWAP\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AA0A5429B8ADA", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\tqc.cx(0, 1) \n\tqc.cx(1, 0) \n    qc.cx(0, 1) \n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AA0A5429B8ADA", "submission_order": 2, "result": "AC", "execution_time": "1926 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1) \n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AA0FBCE83346B", "submission_order": 1, "result": "AC", "execution_time": "2587 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AA1C4A01EA87A", "submission_order": 1, "result": "AC", "execution_time": "1851 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AA6587125D21A", "submission_order": 1, "result": "AC", "execution_time": "2555 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(1,0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AB48BE1A82A32", "submission_order": 1, "result": "AC", "execution_time": "1998 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AB49DCAC2241E", "submission_order": 1, "result": "AC", "execution_time": "2775 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "ABB0627677393", "submission_order": 1, "result": "AC", "execution_time": "2113 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "ABC873767504D", "submission_order": 1, "result": "AC", "execution_time": "2554 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "ABFF7857E4148", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_A2", "user": "AC14B81928570", "submission_order": 1, "result": "WA", "execution_time": "1617 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AC14B81928570", "submission_order": 2, "result": "AC", "execution_time": "1644 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AC6823B5750A9", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "ACD0C4AE0803B", "submission_order": 1, "result": "AC", "execution_time": "2014 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AD057E17F42E6", "submission_order": 1, "result": "WA", "execution_time": "1747 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AD057E17F42E6", "submission_order": 2, "result": "WA", "execution_time": "1748 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AD057E17F42E6", "submission_order": 3, "result": "AC", "execution_time": "2053 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AD5B110A07AFE", "submission_order": 1, "result": "AC", "execution_time": "1820 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AD89F2C46DC5D", "submission_order": 1, "result": "AC", "execution_time": "1816 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "ADC06FA995E0E", "submission_order": 1, "result": "AC", "execution_time": "1932 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "ADED6DE2D6174", "submission_order": 1, "result": "WA", "execution_time": "2188 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "ADED6DE2D6174", "submission_order": 2, "result": "AC", "execution_time": "1979 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE3429CFF60EF", "submission_order": 1, "result": "AC", "execution_time": "2060 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n \n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE3B39717BD5F", "submission_order": 1, "result": "AC", "execution_time": "2031 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE76809252132", "submission_order": 1, "result": "AC", "execution_time": "1715 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE96139E79D9F", "submission_order": 1, "result": "AC", "execution_time": "2022 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE9C59B19C937", "submission_order": 1, "result": "WA", "execution_time": "1780 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE9C59B19C937", "submission_order": 2, "result": "WA", "execution_time": "1797 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE9C59B19C937", "submission_order": 3, "result": "WA", "execution_time": "1944 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE9C59B19C937", "submission_order": 4, "result": "WA", "execution_time": "1670 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE9C59B19C937", "submission_order": 5, "result": "WA", "execution_time": "1646 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE9C59B19C937", "submission_order": 6, "result": "WA", "execution_time": "1834 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE9C59B19C937", "submission_order": 7, "result": "WA", "execution_time": "2438 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AE9C59B19C937", "submission_order": 8, "result": "AC", "execution_time": "2024 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AEFA77FB84D09", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF5B94698938B", "submission_order": 1, "result": "RE", "execution_time": "1554 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap()\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF5B94698938B", "submission_order": 2, "result": "RE", "execution_time": "1615 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF5B94698938B", "submission_order": 3, "result": "RE", "execution_time": "1556 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(1, 2)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF5B94698938B", "submission_order": 4, "result": "UGE", "execution_time": "2012 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF5B94698938B", "submission_order": 5, "result": "WA", "execution_time": "1673 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.x(1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF5B94698938B", "submission_order": 6, "result": "WA", "execution_time": "1925 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF5B94698938B", "submission_order": 7, "result": "AC", "execution_time": "2174 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF857A0E3CBBC", "submission_order": 1, "result": "WA", "execution_time": "1741 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AF857A0E3CBBC", "submission_order": 2, "result": "AC", "execution_time": "2090 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AFBE7C36E4256", "submission_order": 1, "result": "UGE", "execution_time": "1947 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AFBE7C36E4256", "submission_order": 2, "result": "AC", "execution_time": "2002 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AFDE7FED510A4", "submission_order": 1, "result": "AC", "execution_time": "2614 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\tqc.cx(0, 1)\n\tqc.cx(1, 0)\n\tqc.cx(0, 1)\n\treturn qc\n'''"}
{"problem": "QPC004_A2", "user": "AFF00ACE04967", "submission_order": 1, "result": "UGE", "execution_time": "1889 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AFF00ACE04967", "submission_order": 2, "result": "WA", "execution_time": "1716 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A2", "user": "AFF00ACE04967", "submission_order": 3, "result": "AC", "execution_time": "2116 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cx(0, 1)\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A02A0C74024B5", "submission_order": 1, "result": "WA", "execution_time": "1711 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create quantum circuit with n qubits\n    qc = QuantumCircuit(n)\n    \n    # Implement cyclic right shift using CNOT gates\n    # We'll do this from right to left to maintain the correct ordering\n    for i in range(n-1, -1, -1):\n        # Target is current position, control is previous position (cyclically)\n        prev = (i - 1) % n\n        qc.cx(prev, i)\n        \n    # Now uncompute the extra copies, going left to right\n    for i in range(n):\n        # Target is current position, control is previous position (cyclically)\n        prev = (i - 1) % n\n        qc.cx(prev, i)\n        \n    # Finally, apply X gates to swap 0s and 1s where needed\n    for i in range(n):\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A02A0C74024B5", "submission_order": 2, "result": "WA", "execution_time": "1790 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create quantum circuit with n qubits\n    qc = QuantumCircuit(n)\n    \n    # Implement cyclic right shift using CNOT gates only\n    # For right shift, we need to implement the shift in reverse order\n    # to avoid overwriting values we still need\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    \n    # Final CNOT to wrap around\n    qc.cx(n-1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A02A0C74024B5", "submission_order": 3, "result": "WA", "execution_time": "1683 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create quantum circuit with n qubits\n    qc = QuantumCircuit(n)\n    \n    # Implement cyclic right shift\n    # We need three CNOTs to swap without using SwapGate\n    for i in range(n-1, -1, -1):\n        next_i = (i + 1) % n\n        # These three CNOTs implement the swap operation\n        qc.cx(i, next_i)\n        qc.cx(next_i, i)\n        qc.cx(i, next_i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A02A0C74024B5", "submission_order": 4, "result": "AC", "execution_time": "2376 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Perform the cyclic shift using CNOT and X gates\n    for i in range(n - 1, 0, -1):\n        qc.cx(i - 1, i)\n        qc.cx(i, i - 1)\n        qc.cx(i - 1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A05C6BFD61678", "submission_order": 1, "result": "WA", "execution_time": "2197 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Implement the right shift using CX gates\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n    \n    # Swap the first and last qubits\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A0A5CB254D252", "submission_order": 1, "result": "AC", "execution_time": "1833 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(0,n-1)\n    qc.cx(n-1,0)\n    qc.cx(0,n-1)\n    for i in range(n-1,1,-1):\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A15FA347B14C3", "submission_order": 1, "result": "WA", "execution_time": "1919 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        swap(qc, i, i+1)\n        print(i,i+1)\n    if not n==2:\n        swap(qc, n-1, 0)\n        print(n-1,0)\n \n    return qc\n\ndef swap(qc, a, b):\n    qc.cx(a, b)\n    qc.cx(b, a)\n    qc.cx(a, b)\n'''"}
{"problem": "QPC004_A3", "user": "A15FA347B14C3", "submission_order": 2, "result": "WA", "execution_time": "1849 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        swap(qc, i, i+1)\n    if not n==2:\n        swap(qc, n-1, 0)\n \n    return qc\n\ndef swap(qc, a, b):\n    qc.cx(a, b)\n    qc.cx(b, a)\n    qc.cx(a, b)\n'''"}
{"problem": "QPC004_A3", "user": "A15FA347B14C3", "submission_order": 3, "result": "WA", "execution_time": "1713 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    if n != 2:\n        qc.cx(n-1, 0)\n        qc.cx(0, n-1)\n        qc.cx(n-1, 0)\n \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A15FA347B14C3", "submission_order": 4, "result": "RE", "execution_time": "1533 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        swap(qc, n-1, i)\n \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A15FA347B14C3", "submission_order": 5, "result": "AC", "execution_time": "1982 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        swap(qc, n-1, i)\n \n    return qc\n\ndef swap(qc, a, b):\n    qc.cx(a, b)\n    qc.cx(b, a)\n    qc.cx(a, b)\n'''"}
{"problem": "QPC004_A3", "user": "A1773CCC418C9", "submission_order": 1, "result": "AC", "execution_time": "2020 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2,-1,-1):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A1FAA186F433B", "submission_order": 1, "result": "WA", "execution_time": "1692 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        index = n - i - 1\n        qc.cx(index - 1, index)\n        qc.cx(index, index - 1)\n        qc.cx(index - 1, index)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A1FAA186F433B", "submission_order": 2, "result": "AC", "execution_time": "2289 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n - 1):\n        index = n - i - 1\n        qc.cx(index - 1, index)\n        qc.cx(index, index - 1)\n        qc.cx(index - 1, index)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A219713B4BAA7", "submission_order": 1, "result": "AC", "execution_time": "2182 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef my_swap(qc, q1, q2):\n    qc.cx(q1, q2)\n    qc.cx(q2, q1)\n    qc.cx(q1, q2)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n    \tmy_swap(qc, i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A25864DB76895", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        cx.(n-i, 0)\n        cx.(0, n-i)\n        cx.(n-i,0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A25864DB76895", "submission_order": 2, "result": "RE", "execution_time": "1584 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.cx(n-i, 0)\n        qc.cx(0, n-i)\n        qc.cx(n-i,0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A25864DB76895", "submission_order": 3, "result": "WA", "execution_time": "2046 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (1, n-1):\n        qc.cx(n-i, 0)\n        qc.cx(0, n-i)\n        qc.cx(n-i,0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A25864DB76895", "submission_order": 4, "result": "AC", "execution_time": "1889 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.cx(n-1, i)\n        qc.cx(i, n-1)\n        qc.cx(n-1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A29EA91FB0EF8", "submission_order": 1, "result": "RE", "execution_time": "2991 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.x(n - i - 1, n - i - 2)\n        qc.x(n - i - 2, n - i - 1)\n        qc.x(n - i - 1, n - i - 2)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A29EA91FB0EF8", "submission_order": 2, "result": "AC", "execution_time": "2134 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(n - i - 1, n - i - 2)\n        qc.cx(n - i - 2, n - i - 1)\n        qc.cx(n - i - 1, n - i - 2)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A2F7BCD5DA34A", "submission_order": 1, "result": "WA", "execution_time": "3000 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A2F7BCD5DA34A", "submission_order": 2, "result": "WA", "execution_time": "2487 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0,n-1)\n    qc.cx(n-1,0)\n    qc.cx(0,n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A2F7BCD5DA34A", "submission_order": 3, "result": "WA", "execution_time": "2530 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0,n-1)\n    qc.cx(n-1,0)\n    qc.cx(0,n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A2F7BCD5DA34A", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(reversed(1, n):\n        qc.cx(i-2,i-1)\n        qc.cx(i-1,i-2)\n        qc.cx(i-2,i-1)    \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A2F7BCD5DA34A", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(reversed(1, n):\n        qc.cx(i-2,i-1)\n        qc.cx(i-1,i-2)\n        qc.cx(i-2,i-1)    \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A2F7BCD5DA34A", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(reversed(1, n+1):\n        qc.cx(i-2,i-1)\n        qc.cx(i-1,i-2)\n        qc.cx(i-2,i-1)    \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A2F7BCD5DA34A", "submission_order": 7, "result": "WA", "execution_time": "2094 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(1, n+1)):\n        qc.cx(i-2,i-1)\n        qc.cx(i-1,i-2)\n        qc.cx(i-2,i-1)    \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A2F7BCD5DA34A", "submission_order": 8, "result": "AC", "execution_time": "2553 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(1, n)):\n        qc.cx(i-1,i)\n        qc.cx(i-0,i-1)\n        qc.cx(i-1,i)    \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3626F5FD0829", "submission_order": 1, "result": "AC", "execution_time": "1962 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    def swap(a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    # Write your code here:\n    def cyc(L, R):\n        if R - L == 1:\n            return\n        mid = (L + R) // 2\n        swap(mid - 1, R - 1)\n        cyc(L, mid)\n        cyc(mid, R)\n\n    cyc(0, n)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A37E68B3E0087", "submission_order": 1, "result": "AC", "execution_time": "2047 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for q in range(n-1, 0, -1):\n        qc.cx(q, q-1)\n        qc.cx(q-1, q)\n        qc.cx(q, q-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3A4A39D4E928", "submission_order": 1, "result": "AC", "execution_time": "2089 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3E9A36B574E3", "submission_order": 1, "result": "WA", "execution_time": "1771 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n//2):\n        qc.cx(i, n-i-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3E9A36B574E3", "submission_order": 2, "result": "WA", "execution_time": "1747 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 0, -1):\n        qc.cx(i - 1, i)\n    qc.cx(n-1, 0)  \n    return qc\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3E9A36B574E3", "submission_order": 3, "result": "WA", "execution_time": "1980 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 0, -1):\n        qc.cx(i - 1, i)\n    qc.cx(n-1, 0)  \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3E9A36B574E3", "submission_order": 4, "result": "WA", "execution_time": "1773 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    qc.cx(n-1, 0)  \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3E9A36B574E3", "submission_order": 5, "result": "WA", "execution_time": "1756 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n        qc.cx(i, i + 1)\n    qc.cx(n-1, 0)  \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3E9A36B574E3", "submission_order": 6, "result": "WA", "execution_time": "1704 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2):\n        qc.cx(0, i + 1)\n        qc.cx(i + 1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3E9A36B574E3", "submission_order": 7, "result": "WA", "execution_time": "1670 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n        qc.cx(i + 1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A3E9A36B574E3", "submission_order": 8, "result": "AC", "execution_time": "3000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n        qc.cx(i + 1, 0)\n        qc.cx(0, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A40338E820277", "submission_order": 1, "result": "WA", "execution_time": "1811 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n\n    qc.cx(n - 1, 0)\n    qc.cx(0, n - 1)\n    qc.cx(n - 1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A40338E820277", "submission_order": 2, "result": "WA", "execution_time": "1857 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 2:\n        qc.cx(0, 1)\n        qc.cx(1, 0)\n        qc.cx(0, 1)\n    else:\n        for i in range(n - 1):\n            qc.cx(i, i + 1)\n            qc.cx(i + 1, i)\n            qc.cx(i, i + 1)\n        qc.cx(n - 1, 0)\n        qc.cx(0, n - 1)\n        qc.cx(n - 1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A4509AD7D156F", "submission_order": 1, "result": "AC", "execution_time": "2032 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cx(0,i)\n        qc.cx(i,0)\n        qc.cx(0,i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A468FBCA65854", "submission_order": 1, "result": "AC", "execution_time": "1989 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in range(n-2,-1,-1):\n        qc.cx(_,_+1)\n        qc.cx(_+1,_)\n        qc.cx(_,_+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A4A55D32DF780", "submission_order": 1, "result": "RE", "execution_time": "1774 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(n-1, n)\n        qc.cx(n, n-1)\n        qc.cx(n-1, n)\n    \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A4A55D32DF780", "submission_order": 2, "result": "AC", "execution_time": "2109 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A4EA963E08A64", "submission_order": 1, "result": "UGE", "execution_time": "1759 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.swap(i, i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A4EA963E08A64", "submission_order": 2, "result": "AC", "execution_time": "2346 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 1, "result": "RE", "execution_time": "1621 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        \n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 2, "result": "RE", "execution_time": "1736 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        \n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 3, "result": "RE", "execution_time": "1768 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        \n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 4, "result": "WA", "execution_time": "1889 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        \n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 5, "result": "WA", "execution_time": "1966 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n):\n        qc.cx(i, i-1)\n        \n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 6, "result": "RE", "execution_time": "1905 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, N):\n        # 1 ~ N-1까지 반복\n        at = N-i-1\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 7, "result": "RE", "execution_time": "1869 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n):\n        # 1 ~ N-1까지 반복\n        at = n-i-1\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 8, "result": "WA", "execution_time": "1887 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-2, 0, -1):\n        # 1 ~ N-1까지 반복\n        at = n-i-1\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A500D5C275BDE", "submission_order": 9, "result": "AC", "execution_time": "2525 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n):\n        # 1 ~ N-1까지 반복\n        at = n-i-1\n        qc.cx(at, at+1)\n        qc.cx(at+1, at)\n        qc.cx(at, at+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A54DE03EC7D31", "submission_order": 1, "result": "AC", "execution_time": "2661 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-i-1, n-i-2)\n        qc.cx(n-i-2, n-i-1)\n        qc.cx(n-i-1, n-i-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A57F3F25D604E", "submission_order": 1, "result": "AC", "execution_time": "2863 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx((n-i)%n, n-i-1)\n        qc.cx(n-i-1, (n-i)%n)\n        qc.cx((n-i)%n, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A58021B099F7F", "submission_order": 1, "result": "WA", "execution_time": "1791 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.cx(i, (i + 1) % n)\n \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A58021B099F7F", "submission_order": 2, "result": "WA", "execution_time": "1765 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.cx(i, (i + 1) % n)\n        qc.cx((i + 1) % n, i)\n        qc.cx(i, (i + 1) % n)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A58021B099F7F", "submission_order": 3, "result": "AC", "execution_time": "1985 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.cx(i, n-1)\n        qc.cx(n-1, i)\n        qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A58B025C66957", "submission_order": 1, "result": "WA", "execution_time": "1990 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.cx(i, i-1);\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A58B025C66957", "submission_order": 2, "result": "AC", "execution_time": "2355 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A5D5003B44447", "submission_order": 1, "result": "AC", "execution_time": "2486 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 0, -1):\n        qc.cx(i - 1, i)\n        qc.cx(i, i - 1)\n        qc.cx(i - 1, i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A608D131EA68B", "submission_order": 1, "result": "AC", "execution_time": "1835 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    def _swap(i, j):\n        #qc.swap(i, j)\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n\n    curr = list(range(n))\n    while True:\n        need_replace = []\n\n        for idx in range(n):\n            if curr[idx] != (idx + n - 1) % n:\n                need_replace.append(idx)\n\n        for idx in range(0, len(need_replace), 2):\n            if idx+1 >= len(need_replace):\n                continue\n\n            a = need_replace[idx]\n            b = need_replace[idx + 1]\n            _swap(a, b)\n            curr[a], curr[b] = curr[b], curr[a]\n\n        if len(need_replace) == 0:\n            break\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A64FAB399B8F6", "submission_order": 1, "result": "AC", "execution_time": "2173 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef swap(qc: QuantumCircuit, a: int, b: int) -> None:\n    qc.cx(a, b)\n    qc.cx(b, a)\n    qc.cx(a, b)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n - 1, 0, -1):\n        swap(qc, i, i - 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A65DCEF9BC018", "submission_order": 1, "result": "WA", "execution_time": "2130 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        x = (i + 1) % n\n        qc.cx(i, x)\n        qc.cx(x, i)\n        qc.cx(i, x)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A65DCEF9BC018", "submission_order": 2, "result": "RE", "execution_time": "1745 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.cx(i, x)\n        qc.cx(x, i)\n        qc.cx(i, x)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A65DCEF9BC018", "submission_order": 3, "result": "WA", "execution_time": "1972 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        x = i+1\n        qc.cx(i, x)\n        qc.cx(x, i)\n        qc.cx(i, x)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A65DCEF9BC018", "submission_order": 4, "result": "RE", "execution_time": "1789 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1, -1, -1):\n        x = i+1\n        qc.cx(i, x)\n        qc.cx(x, i)\n        qc.cx(i, x)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A65DCEF9BC018", "submission_order": 5, "result": "AC", "execution_time": "2037 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-2, -1, -1):\n        x = i+1\n        qc.cx(i, x)\n        qc.cx(x, i)\n        qc.cx(i, x)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6714A3AF89AA", "submission_order": 1, "result": "UGE", "execution_time": "1620 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n        qc.swap(i,i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6714A3AF89AA", "submission_order": 2, "result": "AC", "execution_time": "1949 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6BF1E2647938", "submission_order": 1, "result": "WA", "execution_time": "1852 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    swap(qc, 0, n-1)\n    for i in range(n - 1):\n        swap(qc, n - i - 1, n - i - 2)\n\n    return qc\n\ndef swap(qc, q1, q2) -> QuantumCircuit:\n    qc.cx(q1, q2)\n    qc.cx(q2, q1)\n    qc.cx(q1, q2)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6BF1E2647938", "submission_order": 2, "result": "AC", "execution_time": "2588 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    swap(qc, 0, n-1)\n    for i in range(n - 2):\n        swap(qc, n - i - 1, n - i - 2)\n\n    return qc\n\ndef swap(qc, q1, q2) -> QuantumCircuit:\n    qc.cx(q1, q2)\n    qc.cx(q2, q1)\n    qc.cx(q1, q2)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6CC3335A7693", "submission_order": 1, "result": "AC", "execution_time": "1879 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 1, "result": "RE", "execution_time": "1770 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n)\n    for i in range(1, n):\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 2, "result": "RE", "execution_time": "1899 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n)\n    for i in range(1, n):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 3, "result": "WA", "execution_time": "2338 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(1, n-1):\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 4, "result": "WA", "execution_time": "2012 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(1, n-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 5, "result": "WA", "execution_time": "2140 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(1, n-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 6, "result": "WA", "execution_time": "2079 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(1, n-1):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 7, "result": "WA", "execution_time": "1928 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(0, n-2):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 8, "result": "WA", "execution_time": "1806 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(0, n-2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 9, "result": "WA", "execution_time": "1857 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(0, n-2):\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 10, "result": "WA", "execution_time": "1856 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(0, n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 11, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.(0)\n    for i in range(0, n-2):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 12, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.(0)\n    for i in range(0, n-2):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 13, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.(0)\n    for i in range(0, n-2):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 14, "result": "WA", "execution_time": "1938 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(0, n-2):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 15, "result": "WA", "execution_time": "1684 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(1, n-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 16, "result": "WA", "execution_time": "1961 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(n-1, 0)\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 17, "result": "WA", "execution_time": "1701 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(n-1, 0)\n    for i in range(n-1, 1, -1):\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 18, "result": "WA", "execution_time": "1735 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 19, "result": "WA", "execution_time": "1589 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(n-1, 0)\n    for i in range(n-1):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 20, "result": "WA", "execution_time": "1983 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(n-1):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 21, "result": "WA", "execution_time": "1843 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(1, n-1):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 22, "result": "WA", "execution_time": "1866 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    for i in range(n-1, 1, -1):\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 23, "result": "WA", "execution_time": "1617 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    for i in range(n-1, 2, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A6F05DC2BB2DB", "submission_order": 24, "result": "WA", "execution_time": "1649 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    for i in range(n-2, 1, -1):\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A71DE42CDCFB2", "submission_order": 1, "result": "UGE", "execution_time": "1763 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.swap(0,i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A71DE42CDCFB2", "submission_order": 2, "result": "AC", "execution_time": "2003 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(0,i+1)\n        qc.cx(i+1,0)\n        qc.cx(0,i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A73C218040EF6", "submission_order": 1, "result": "RE", "execution_time": "2121 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A73C218040EF6", "submission_order": 2, "result": "AC", "execution_time": "2529 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A74623E2A126C", "submission_order": 1, "result": "WA", "execution_time": "1771 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A74623E2A126C", "submission_order": 2, "result": "AC", "execution_time": "1956 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A749679250715", "submission_order": 1, "result": "WA", "execution_time": "1800 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2, -1):\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A749679250715", "submission_order": 2, "result": "AC", "execution_time": "2088 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2, -1, -1):\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A77D3E746EC50", "submission_order": 1, "result": "AC", "execution_time": "2370 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # CNOT3つでSWAPを実装する関数\n    def swap_with_cnot(a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    # 右端(n-1番量子ビット)を左へずらす → 次に(n-2)番をずらす → ... の順\n    # 具体例: n=3の場合、qubit2<->qubit1、続いてqubit1<->qubit0 の順\n    for i in range(n-1, 0, -1):\n        swap_with_cnot(i, i-1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A78F82C20C080", "submission_order": 1, "result": "WA", "execution_time": "1874 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2,0):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A78F82C20C080", "submission_order": 2, "result": "WA", "execution_time": "1868 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2,0,-1):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A78F82C20C080", "submission_order": 3, "result": "AC", "execution_time": "2023 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2,-1,-1):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A793A22B67475", "submission_order": 1, "result": "AC", "execution_time": "1940 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2, -1, -1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7A9EBF5812E2", "submission_order": 1, "result": "WA", "execution_time": "1944 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1,n):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7A9EBF5812E2", "submission_order": 2, "result": "WA", "execution_time": "1883 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7A9EBF5812E2", "submission_order": 3, "result": "AC", "execution_time": "1938 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7AA7D773634A", "submission_order": 1, "result": "WA", "execution_time": "1941 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7AA7D773634A", "submission_order": 2, "result": "WA", "execution_time": "1608 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7AA7D773634A", "submission_order": 3, "result": "AC", "execution_time": "2059 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7EF366B1B0E6", "submission_order": 1, "result": "WA", "execution_time": "1746 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # n qubitのn番目のqubitを0番目にスワップする、swapゲートを使わない実装\n    for i in range(0,len(qc)):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i) \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7EF366B1B0E6", "submission_order": 2, "result": "WA", "execution_time": "1956 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # n qubitのn番目のqubitを0番目にスワップする、swapゲートを使わない実装\n    for n in range(0,len(qc)):\n        qc.cx(n-1, n)\n        qc.cx(n, n-1)\n        qc.cx(n-1, n) \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7EF366B1B0E6", "submission_order": 3, "result": "WA", "execution_time": "1730 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # n qubitのn番目のqubitを0番目にスワップする、swapゲートを使わない実装\n    for i in range(0,n):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)   \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7EF366B1B0E6", "submission_order": 4, "result": "RE", "execution_time": "1763 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # n qubitのn番目のqubitを0番目にスワップする、swapゲートを使わない実装\n    for i in range(0,n):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)   \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7EF366B1B0E6", "submission_order": 5, "result": "RE", "execution_time": "1761 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # n qubitのn番目のqubitを0番目にスワップする、swapゲートを使わない実装\n    for i in range(0,n):     \n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7EF366B1B0E6", "submission_order": 6, "result": "RE", "execution_time": "1523 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0,n):     \n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7EF366B1B0E6", "submission_order": 7, "result": "AC", "execution_time": "2687 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0,n-1):     \n        qc.cx(i,n-1)\n        qc.cx(n-1,i)\n        qc.cx(i,n-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 1, "result": "RE", "execution_time": "1673 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n-1-i)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 2, "result": "RE", "execution_time": "1781 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i,n-1-i)\n        qc.cx(n-1-i,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 3, "result": "RE", "execution_time": "1718 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n >= 2 and n <= 10:\n        for i in range(n):\n            qc.cx(i,n-1-i)\n            qc.cx(n-1-i,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 4, "result": "RE", "execution_time": "2073 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n >= 2 and n <= 10:\n        for i in range(n):\n            qc.cx(i,n-1-i)\n            qc.cx(n-1-i,i)\n\n        return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 5, "result": "RE", "execution_time": "1681 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n):\n        qc.cx(i,n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 6, "result": "WA", "execution_time": "1915 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n//2):\n        qc.cx(i,n-1-i)\n        qc.cx(n-1-i,i)\n        qc.cx(i,n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 7, "result": "RE", "execution_time": "1820 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n):\n        qc.cx(i,n-1-i)\n        qc.cx(n-1-i,i)\n        qc.cx(i,n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 8, "result": "WA", "execution_time": "1676 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n//2):\n        qc.cx(i,(n-1-i))\n        qc.cx((n-1-i),i)\n        qc.cx(i,(n-1-i))\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 9, "result": "WA", "execution_time": "1789 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n//2):\n        qc.cx(i,(n-1-i))\n        qc.cx((n-1-i),i)\n        qc.cx(i,(n-1-i))\n        qc.barrier()\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 10, "result": "WA", "execution_time": "1920 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n//2):\n        qc.cx(i,(n-i-1))\n        qc.cx((n-i-1),i)\n        qc.cx(i,(n-i-1))\n        qc.barrier()\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 11, "result": "WA", "execution_time": "1796 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n//2):\n        qc.cx(i,(n-1-i))\n        qc.cx((n-1-i),i)\n        qc.cx(i,(n-1-i))\n        qc.barrier()\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 12, "result": "WA", "execution_time": "1914 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.cx(n-1,0)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A7F6F74ED8E62", "submission_order": 13, "result": "WA", "execution_time": "2092 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here\n    for i in range(n//2):\n        qc.cx(i,(n-i-1))\n        qc.cx((n-i-1),i)\n        qc.cx(i,(n-i-1))\n        qc.barrier()\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A810623B6C07B", "submission_order": 1, "result": "AC", "execution_time": "2987 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    def swap(n, i, j) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n\n        return qc\n\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n-1)):\n        qc.compose(swap(n, i, i + 1), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A88ED4BBD92B9", "submission_order": 1, "result": "TOE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n    qc.cx(i-1, i)\n    qc.cx(i, i-1)\n    qc.cx(i-1, i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A88ED4BBD92B9", "submission_order": 2, "result": "TOE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n    qc.cx(i-1, i)\n    qc.cx(i, i-1)\n    qc.cx(i-1, i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A8AF5C92A4CC7", "submission_order": 1, "result": "WA", "execution_time": "1638 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(n - i - 2, n - i - 1)\n        qc.cx(n - i - 1, n - i - 2)\n        qc.cx(n - i - 2, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A8AF5C92A4CC7", "submission_order": 2, "result": "AC", "execution_time": "1939 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(n - i - 2, n - i - 1)\n        qc.cx(n - i - 1, n - i - 2)\n        qc.cx(n - i - 2, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A8ED48ADC9428", "submission_order": 1, "result": "AC", "execution_time": "1955 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.cx(i, n - 1)      # Step 1: CNOT with control q_i and target q_{n-1}\n        qc.cx(n - 1, i)      # Step 2: CNOT with control q_{n-1} and target q_i\n        qc.cx(i, n - 1) \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A94DC720E8A68", "submission_order": 1, "result": "WA", "execution_time": "1752 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, (i + 1) % n)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A94DC720E8A68", "submission_order": 2, "result": "WA", "execution_time": "1860 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i == n - 1:\n            qc.cx(i, 0)\n            qc.cx(0, i)\n            qc.cx(i, 0)\n        else:\n            qc.cx(i, i + 1)\n            qc.cx(i + 1, i)\n            qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A94DC720E8A68", "submission_order": 3, "result": "WA", "execution_time": "1721 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n//2):\n        j = (n-1) - i\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A94DC720E8A68", "submission_order": 4, "result": "AC", "execution_time": "2118 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9611740FCF7A", "submission_order": 1, "result": "WA", "execution_time": "1696 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9611740FCF7A", "submission_order": 2, "result": "RE", "execution_time": "1516 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    def cnot_swap(qc, q1, q2):\n        qc.cx(q1, q2)\n        qc.cx(q2, q1)\n        qc.cx(q1, q2)\n\n    for i in range(n-1):\n        cnot_swap(0, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9611740FCF7A", "submission_order": 3, "result": "AC", "execution_time": "2061 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    def cnot_swap(qc, q1, q2):\n        qc.cx(q1, q2)\n        qc.cx(q2, q1)\n        qc.cx(q1, q2)\n\n    # quantum left shift\n    for i in range(n-1):\n        cnot_swap(qc, 0, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9830937C0209", "submission_order": 1, "result": "WA", "execution_time": "1649 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n    \n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9830937C0209", "submission_order": 2, "result": "WA", "execution_time": "1775 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n    \n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9830937C0209", "submission_order": 3, "result": "WA", "execution_time": "1666 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n    \n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9830937C0209", "submission_order": 4, "result": "WA", "execution_time": "1836 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9830937C0209", "submission_order": 5, "result": "RE", "execution_time": "1737 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9830937C0209", "submission_order": 6, "result": "AC", "execution_time": "2038 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        last = n - 1 - i\n        qc.cx(last, last - 1)\n        qc.cx(last - 1, last)\n        qc.cx(last, last - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A983966302D2D", "submission_order": 1, "result": "WA", "execution_time": "1700 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(n-1,0)\n    qc.cx(0,n-1)\n    qc.cx(n-1,0)\n\n    for i in range(1, n-2):#i and n-1\n        qc.cx(n-1,i)\n        qc.cx(i,n-1)\n        qc.cx(n-1,i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A983966302D2D", "submission_order": 2, "result": "AC", "execution_time": "2190 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(n-1,0)\n    qc.cx(0,n-1)\n    qc.cx(n-1,0)\n\n    for i in range(1, n-1):#i and n-1\n        qc.cx(n-1,i)\n        qc.cx(i,n-1)\n        qc.cx(n-1,i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A986486E88F8B", "submission_order": 1, "result": "RE", "execution_time": "1597 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(n - i    , n - i    )\n        qc.cx(n - i - 1, n - i - 1)\n        qc.cx(n - i    , n - i    )\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A986486E88F8B", "submission_order": 2, "result": "RE", "execution_time": "1593 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n - 1):\n        qc.cx(n - i    , n - i    )\n        qc.cx(n - i - 1, n - i - 1)\n        qc.cx(n - i    , n - i    )\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A986486E88F8B", "submission_order": 3, "result": "RE", "execution_time": "1862 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n - 1):\n        qc.cx(n - i    , n - i - 1)\n        qc.cx(n - i - 1, n - i    )\n        qc.cx(n - i    , n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A986486E88F8B", "submission_order": 4, "result": "AC", "execution_time": "2358 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(0, n - 1)):\n        qc.cx(i - 1, i    )\n        qc.cx(i    , i - 1)\n        qc.cx(i - 1, i    )\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A98F0B98744C1", "submission_order": 1, "result": "WA", "execution_time": "1684 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_A3", "user": "A98F0B98744C1", "submission_order": 2, "result": "AC", "execution_time": "1871 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_A3", "user": "A9F0BEF7AB60E", "submission_order": 1, "result": "WA", "execution_time": "1782 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n-1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "A9F0BEF7AB60E", "submission_order": 2, "result": "AC", "execution_time": "2542 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(0, n-1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA0DFEFEB6A49", "submission_order": 1, "result": "WA", "execution_time": "2247 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n : int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.cx(i,(i+1)%n)\n        qc.cx(i,(i+1)%n)\n        qc.cx(i,(i+1)%n)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA0DFEFEB6A49", "submission_order": 2, "result": "WA", "execution_time": "1698 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n : int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.cx(i,(i+1)%n)\n        qc.cx((i+1)%n,i)\n        qc.cx(i,(i+1)%n)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA0DFEFEB6A49", "submission_order": 3, "result": "RE", "execution_time": "1550 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n : int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n,1,-1):\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA0DFEFEB6A49", "submission_order": 4, "result": "AC", "execution_time": "1954 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n : int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1,0,-1):\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA33D652C6670", "submission_order": 1, "result": "UGE", "execution_time": "2559 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in reversed(range(n - 1)):\n\t\tqc.swap(i, i + 1)\n\treturn qc\n'''"}
{"problem": "QPC004_A3", "user": "AA33D652C6670", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in reversed(range(n - 1)):\n\t\tqc.cx(i, i + 1)\n\t\tqc.cx(i + 1, i)\n\t\tqc.cx(i, i + 1)\n\treturn qc\n'''"}
{"problem": "QPC004_A3", "user": "AA4D4865988AE", "submission_order": 1, "result": "WA", "execution_time": "1924 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.cx(n-1,0)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA4D4865988AE", "submission_order": 2, "result": "RE", "execution_time": "1614 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,i+1)\n        qc.cx(i+1,1)\n        qc.cx(i,i+1)\n    qc.cx(n-1,0)\n    qc.cx(0,n-1)\n    qc.cx(n-1,0)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA4D4865988AE", "submission_order": 3, "result": "RE", "execution_time": "1605 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    for i in range(n-1):\n        qc.cx(i+1,1)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    qc.cx(n-1,0)\n    qc.cx(0,n-1)\n    qc.cx(n-1,0)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA4D4865988AE", "submission_order": 4, "result": "WA", "execution_time": "1675 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc, a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    swap(qc, n-1, 0)\n    for i in range(n-2, -1, -1):\n        swap(qc, i, i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA4D4865988AE", "submission_order": 5, "result": "AC", "execution_time": "2237 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc, a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    swap(qc, n-1, 0)\n    for i in range(n-2, 0, -1):\n        swap(qc, i, i+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA5AA1BF51896", "submission_order": 1, "result": "WA", "execution_time": "1750 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i*2,i*2+1)\n        qc.cx(i*2+1,i*2)\n        qc.cx(i*2,i*2+1)\n    for i in range(-(-n//2)//2):\n        qc.cx(i*4,i*4+2)\n        qc.cx(i*4+2,i*4)\n        qc.cx(i*4,i*4+2)\n    for i in range(-(-n//4)//2):\n        qc.cx(i*8,i*8+4)\n        qc.cx(i*8+4,i*8)\n        qc.cx(i*8,i*8+4)\n    for i in range(-(-n//8)//2):\n        qc.cx(i*16,i*16+8)\n        qc.cx(i*16+8,i*16)\n        qc.cx(i*16,i*16+4)\n    \n        \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AA5AA1BF51896", "submission_order": 2, "result": "AC", "execution_time": "2110 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i*2,i*2+1)\n        qc.cx(i*2+1,i*2)\n        qc.cx(i*2,i*2+1)\n    for i in range(-(-n//2)//2):\n        qc.cx(i*4,i*4+2)\n        qc.cx(i*4+2,i*4)\n        qc.cx(i*4,i*4+2)\n    for i in range(-(-n//4)//2):\n        qc.cx(i*8,i*8+4)\n        qc.cx(i*8+4,i*8)\n        qc.cx(i*8,i*8+4)\n    for i in range(-(-n//8)//2):\n        qc.cx(i*16,i*16+8)\n        qc.cx(i*16+8,i*16)\n        qc.cx(i*16,i*16+8)\n    \n        \n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AAC5A10689B25", "submission_order": 1, "result": "AC", "execution_time": "1815 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\n\ndef solve(n : int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.cx(i+1, 0)\n        qc.cx(0, i+1)\n        qc.cx(i+1, 0)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AAC76210D2586", "submission_order": 1, "result": "AC", "execution_time": "2296 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AAD5FA01AF0C8", "submission_order": 1, "result": "WA", "execution_time": "1966 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-2, n-1)\n        qc.cx(n-1, n-2)\n        qc.cx(n-2, n-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AAD5FA01AF0C8", "submission_order": 2, "result": "AC", "execution_time": "2237 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-2-i, n-1-i)\n        qc.cx(n-1-i, n-2-i)\n        qc.cx(n-2-i, n-1-i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB0EABB98A646", "submission_order": 1, "result": "AC", "execution_time": "2001 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, n-1)\n        qc.cx(n-1, i)\n        qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB10F7FFB2E2C", "submission_order": 1, "result": "AC", "execution_time": "2863 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2, -1, -1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 1, "result": "WA", "execution_time": "1928 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    for i in range(n-1)[::-1]:\n        qc.cx(i+1, i) \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 2, "result": "WA", "execution_time": "1791 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 3, "result": "WA", "execution_time": "1860 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(n-1, 0) \n    qc.cx(n-2, n-1) \n    for i in range(n-2, 0, -1): \n        qc.cx(i, i + 1)\n    qc.cx(0, n-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 4, "result": "WA", "execution_time": "1910 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i + 1)\n    qc.cx(n-1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 5, "result": "WA", "execution_time": "1832 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i + 1)\n    qc.cx(n-1, 0)\n    for i in range(n-1):\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 6, "result": "WA", "execution_time": "1559 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i + 1)\n    qc.cx(n-1, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 7, "result": "WA", "execution_time": "1875 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 8, "result": "WA", "execution_time": "1595 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB3576D02CC60", "submission_order": 9, "result": "AC", "execution_time": "2252 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    for i in range(1, n-1)[::-1]:\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB73C88866C46", "submission_order": 1, "result": "UGE", "execution_time": "1548 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.swap(n - 2 - i, n - 1 - i)\n        qc.swap(n - 1 - i, n - 2 - i)\n        qc.swap(n - 2 - i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AB73C88866C46", "submission_order": 2, "result": "AC", "execution_time": "1844 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(n - 2 - i, n - 1 - i)\n        qc.cx(n - 1 - i, n - 2 - i)\n        qc.cx(n - 2 - i, n - 1 - i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "ABF425312C2FA", "submission_order": 1, "result": "AC", "execution_time": "2466 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        j = n-1-i\n        k = n-2-i\n        qc.cx(j,k)\n        qc.cx(k,j)\n        qc.cx(j,k)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AC175B6D87E0A", "submission_order": 1, "result": "AC", "execution_time": "2131 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n//2):\n        qc.cx(i, n - 1 - i)\n        qc.cx(n - 1 - i, i)\n        qc.cx(i, n - 1 - i)\n    for i in range(1, n//2 + n%2):\n        qc.cx(i, n - i)\n        qc.cx(n - i, i)\n        qc.cx(i, n - i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AC7927B79D842", "submission_order": 1, "result": "AC", "execution_time": "2460 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "ACB63A703A384", "submission_order": 1, "result": "AC", "execution_time": "2082 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-i-1, n-i-2)\n        qc.cx(n-i-2, n-i-1)\n        qc.cx(n-i-1, n-i-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AD038E396B29B", "submission_order": 1, "result": "WA", "execution_time": "1746 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Move the last qubit to the first position\n    for i in range(n-1):\n        qc.cx(n-1, i)  # CNOT from qubit n-1 to qubit i\n    \n    # Move the first qubit to the second position\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)  # CNOT from qubit i-1 to qubit i\n    \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AD7780C3F60A0", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef swap_gate(qc, i, j)\n    qc.cx(i, j)\n    qc.cx(j, i)\n    qc.cx(i, j)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #i refers to x_{n-1}\n    for i in range(n-1, 0, -1):\n        qc = swap_gate(qc, i, i-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AD7780C3F60A0", "submission_order": 2, "result": "AC", "execution_time": "2256 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef swap_gate(qc, i, j):\n    qc.cx(i, j)\n    qc.cx(j, i)\n    qc.cx(i, j)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #i refers to x_{n-1}\n    for i in range(n-1, 0, -1):\n        qc = swap_gate(qc, i, i-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AD8694F876030", "submission_order": 1, "result": "AC", "execution_time": "2057 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n \n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "ADE2DB20547C0", "submission_order": 1, "result": "UGE", "execution_time": "1980 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    swap = QuantumCircuit(2)\n    swap.cx(0,1)\n    swap.cx(1,0)\n    swap.cx(0,1)\n\n    for i in range(n-1):\n        i_first=i\n        i_second=(i+1) % n\n        qc.append(swap.to_instruction(), [i_first, i_second])\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "ADE2DB20547C0", "submission_order": 2, "result": "WA", "execution_time": "2222 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-1):\n        i_first=i\n        i_second=(i+1) % n\n        qc.cx(i_first, i_second)\n        qc.cx(i_second, i_first)\n        qc.cx(i_first, i_second)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "ADE2DB20547C0", "submission_order": 3, "result": "AC", "execution_time": "2536 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in reversed(range(n-1)):\n        i_first=i\n        i_second=(i+1) % n\n        qc.cx(i_first, i_second)\n        qc.cx(i_second, i_first)\n        qc.cx(i_first, i_second)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "ADE561D096603", "submission_order": 1, "result": "AC", "execution_time": "2017 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if n-i-2 < 0:\n            break\n        qc.cx(n-i-2,n-i-1)\n        qc.cx(n-i-1, n-i-2)\n        qc.cx(n-i-2, n-i-1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE002C199A9CA", "submission_order": 1, "result": "WA", "execution_time": "1836 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc,k,l):\n        qc.cx(k,l)\n        qc.cx(l,k)\n        qc.cx(k,l)\n        return qc\n        \n    for j in range(n):\n        qc=swap(qc,j,(j+1)%n)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE002C199A9CA", "submission_order": 2, "result": "AC", "execution_time": "1999 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc,k,l):\n        qc.cx(k,l)\n        qc.cx(l,k)\n        qc.cx(k,l)\n        return qc\n        \n    for j in range(n-1):\n        qc=swap(qc,0,j+1)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE033A2D1F1D8", "submission_order": 1, "result": "WA", "execution_time": "1608 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE033A2D1F1D8", "submission_order": 2, "result": "WA", "execution_time": "1749 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE1D6323D4D04", "submission_order": 1, "result": "AC", "execution_time": "1992 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    def swap(a,b):\n    \tqc.cx(a,b)\n    \tqc.cx(b,a)\n    \tqc.cx(a,b)\n          \t\n    for i in range(n-1)[::-1]:\n    \tswap(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE33E87DCA8F7", "submission_order": 1, "result": "AC", "execution_time": "1848 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(1, n):\n        qc.cx(0, i)\n        qc.cx(i, 0)\n        qc.cx(0, i)\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE4F65FF335DA", "submission_order": 1, "result": "WA", "execution_time": "1921 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n // 2):\n    \n        qc.cx(i, n - i - 1)  \n        qc.cx(n - i - 1, i)  \n        qc.cx(i, n - i - 1)  \n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE4F65FF335DA", "submission_order": 2, "result": "AC", "execution_time": "2240 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE6F132F86D54", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n     for i in range(n-1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    \n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE6F132F86D54", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n     for i in range(n-1,0,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE6F132F86D54", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n     for i in range(n-1,0,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE6F132F86D54", "submission_order": 4, "result": "WA", "execution_time": "1893 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n    for i in range(n-1,0,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE6F132F86D54", "submission_order": 5, "result": "WA", "execution_time": "1750 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1,0,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE6F132F86D54", "submission_order": 6, "result": "WA", "execution_time": "1874 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1,1,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE6F132F86D54", "submission_order": 7, "result": "AC", "execution_time": "2083 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n    for i in range(n-1,1,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AE9BB2DCE41F5", "submission_order": 1, "result": "AC", "execution_time": "2144 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n-1)):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AEF018AF0F593", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        for j in range(n)\n            for k in range(n)\n                qc.cx(j,k+1)\n    \n    for l in range(n)\n        qc.cx(0,l+1)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AEF018AF0F593", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n)\n        for j in range(n)\n            for k in range(n)\n                qc.cx(j,k)\n    \n    for l in range(n)\n        qc.cx(0,l)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AFBF9BA361026", "submission_order": 1, "result": "RE", "execution_time": "1612 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, -1, 0):\n        qc.cx(i, i - 1)\n        qc.cx(i - 1, i)\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AFBF9BA361026", "submission_order": 2, "result": "RE", "execution_time": "1515 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n, 0, -1):\n        qc.cx(i, i - 1)\n        qc.cx(i - 1, i)\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A3", "user": "AFBF9BA361026", "submission_order": 3, "result": "AC", "execution_time": "2576 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i, i - 1)\n        qc.cx(i - 1, i)\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A022C87D5C54B", "submission_order": 1, "result": "AC", "execution_time": "2298 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    j = n-1\n    while j >= 3:\n        qc.cx(j, j-1)\n        qc.cx(j-1, j)\n        qc.cx(j, j-1)\n\n        qc.cx(j-2, j-3)\n        qc.cx(j-3, j-2)\n        qc.cx(j-2, j-3)\n\n        qc.cx(j-1, j-3)\n        qc.cx(j-3, j-1)\n        qc.cx(j-1, j-3)\n        j -= 3\n    \n    while j > 0:\n        qc.cx(j, j-1)\n        qc.cx(j-1, j)\n        qc.cx(j, j-1)\n        j -= 1\n\n    #\"\"\"\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A039445F8504F", "submission_order": 1, "result": "DLE", "execution_time": "1630 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        swap(qc, n - i - 1, n - i - 2)\n\n    return qc\n\ndef swap(qc, q1, q2) -> QuantumCircuit:\n    qc.cx(q1, q2)\n    qc.cx(q2, q1)\n    qc.cx(q1, q2)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A039445F8504F", "submission_order": 2, "result": "WA", "execution_time": "1651 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        swap(qc, n - i - 1, n - i - 2)\n\n    return qc\n\ndef swap(qc, q1, q2) -> QuantumCircuit:\n\n    qc.cx(q2, q1)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A039445F8504F", "submission_order": 3, "result": "AC", "execution_time": "1917 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        swap(qc, n - i - 1, n - i - 2)\n\n    return qc\n\ndef swap(qc, q1, q2) -> QuantumCircuit:\n\n    qc.cx(q2, q1)\n    qc.cx(q1, q2)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A04AB83F5D0C0", "submission_order": 1, "result": "AC", "execution_time": "1917 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A06A10C47EDCB", "submission_order": 1, "result": "WA", "execution_time": "1556 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(1, n)):\n        qc.cx(i-1, i)\n    \n    for i in range(1, n):\n        qc.cx(i-1, i)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A06A10C47EDCB", "submission_order": 2, "result": "AC", "execution_time": "1950 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(1, n)):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0843626AE6F5", "submission_order": 1, "result": "DLE", "execution_time": "1616 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        swap(qc, n-1, i)\n \n    return qc\n\ndef swap(qc, a, b):\n    qc.cx(a, b)\n    qc.cx(b, a)\n    qc.cx(a, b)\n'''"}
{"problem": "QPC004_A4", "user": "A0A63D31F231F", "submission_order": 1, "result": "DLE", "execution_time": "1714 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.cx(i, n-1)\n        qc.cx(n-1, i)\n        qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0A63D31F231F", "submission_order": 2, "result": "WA", "execution_time": "1857 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.cx(n-1, i)\n        qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0A63D31F231F", "submission_order": 3, "result": "WA", "execution_time": "2011 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.cx(i, n-1)\n        qc.cx(n-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0AEA23D0E559", "submission_order": 1, "result": "DLE", "execution_time": "1700 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef swap_gate(qc, i, j):\n    qc.cx(i, j)\n    qc.cx(j, i)\n    qc.cx(i, j)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #i refers to x_{n-1}\n    for i in range(n-1, 0, -1):\n        qc = swap_gate(qc, i, i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0AEA23D0E559", "submission_order": 2, "result": "AC", "execution_time": "1945 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef swap_gate(qc, i, j):\n    qc.cx(j, i)\n    qc.cx(i, j)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #i refers to x_{n-1}\n    for i in range(n-1, 0, -1):\n        qc = swap_gate(qc, i, i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0BE5D04B1CA0", "submission_order": 1, "result": "AC", "execution_time": "2108 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0FAD2673D892", "submission_order": 1, "result": "WA", "execution_time": "1723 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.reset(0)\n\n    for i in range(n-1,1,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0FAD2673D892", "submission_order": 2, "result": "WA", "execution_time": "1844 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n\n\n    for i in range(n-1,1,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    qc.reset(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0FAD2673D892", "submission_order": 3, "result": "WA", "execution_time": "1875 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1,1,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    qc.reset(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0FAD2673D892", "submission_order": 4, "result": "WA", "execution_time": "1935 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1,0,-1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    qc.reset(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A0FAD2673D892", "submission_order": 5, "result": "WA", "execution_time": "1973 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2,-1,-1):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    qc.reset(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A15105F219DF9", "submission_order": 1, "result": "AC", "execution_time": "1915 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A166A53C78DB4", "submission_order": 1, "result": "AC", "execution_time": "1969 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0, -1):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2B42283A3C7C", "submission_order": 1, "result": "RE", "execution_time": "2024 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 2):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    for i in range(n - 1, 2):\n        qc.cx(n - i - 3, n - i - 1)\n        qc.cx(n - i - 1, n - i - 3)\n        qc.cx(n - i - 3, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2B42283A3C7C", "submission_order": 2, "result": "AC", "execution_time": "2263 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n - 1, 2):  \n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    s = (n+1)%2\n    for i in range(s, n - 2, 2): \n        qc.cx(n- i - 3, n- i - 1)\n        qc.cx(n- i - 1, n-i - 3)\n        qc.cx(n-i - 3, n-i - 1)\n        print(n-i-1, n-i-3)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2EA97ED97E99", "submission_order": 1, "result": "RE", "execution_time": "1635 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i*2,i*2+1)\n        qc.cx(i*2+1,i*2)\n        qc.cx(i*2,i*2+1)\n    for i in range(-(-n//2)//2):\n        qc.cx(i*4,i*4+2)\n        qc.cx(i*4+2,i*4)\n        qc.cx(i*4,i*4+2)\n    for i in range(-(-n//4)//2):\n        qc.cx(i*8,i*8+4)\n        qc.cx(i*8+4,i*8)\n        qc.cx(i*8,i*8+4)\n    for i in range(-(-n//8)//2):\n        qc.cx(i*16,i*16+8)\n        qc.cx(i*16+8,i*16)\n        qc.cx(i*16,i*16+8)\n'''"}
{"problem": "QPC004_A4", "user": "A2EA97ED97E99", "submission_order": 2, "result": "AC", "execution_time": "2159 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i*2,i*2+1)\n        qc.cx(i*2+1,i*2)\n        qc.cx(i*2,i*2+1)\n    for i in range(-(-n//2)//2):\n        qc.cx(i*4,i*4+2)\n        qc.cx(i*4+2,i*4)\n        qc.cx(i*4,i*4+2)\n    for i in range(-(-n//4)//2):\n        qc.cx(i*8,i*8+4)\n        qc.cx(i*8+4,i*8)\n        qc.cx(i*8,i*8+4)\n    for i in range(-(-n//8)//2):\n        qc.cx(i*16,i*16+8)\n        qc.cx(i*16+8,i*16)\n        qc.cx(i*16,i*16+8)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 1, "result": "RE", "execution_time": "1631 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * arccos(1 / sqrt(3)) \n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 2, "result": "RE", "execution_time": "2280 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * arccos(1 / sqrt(3)) \n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 3, "result": "WA", "execution_time": "1885 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    theta = 2 * np.arccos(1 / np.sqrt(3))\n    qc.ry(theta, 0)\n    qc.cx(0, 1)\n    qc.cz(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 4, "result": "WA", "execution_time": "1802 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2, 0, -1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 5, "result": "DLE", "execution_time": "1856 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 2:\n        # n=2 の場合、x0 を x1 に移動するだけ\n        qc.cx(0, 1)\n        qc.cx(1, 0)\n        qc.cx(0, 1)\n    else:\n        # 一般的な n の場合\n        for i in range(n - 2, -1, -1):  # x_0 から x_{n-2} まで右にシフト\n            qc.cx(i, i + 1)\n            qc.cx(i + 1, i)\n            qc.cx(i, i + 1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 6, "result": "WA", "execution_time": "1653 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 2:\n        qc.cx(0, 1)\n    else:\n        for i in range(n - 2, -1, -1): \n            qc.cx(i, i + 1) \n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 7, "result": "WA", "execution_time": "1948 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 2:\n        qc.cx(0, 1)\n    else:\n        for i in range(n - 2, -1, -1): \n            qc.cx(i, i + 1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 8, "result": "DLE", "execution_time": "1645 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 2:\n        # n=2 の場合、x0 を x1 に移動するだけ\n        qc.cx(0, 1)\n        qc.cx(1, 0)\n        qc.cx(0, 1)\n    else:\n        # 一般的な n の場合\n        for i in range(n - 2, -1, -1):  # x_0 から x_{n-2} まで右にシフト\n            qc.cx(i, i + 1)\n            qc.cx(i + 1, i)\n            qc.cx(i, i + 1)\n    \n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 9, "result": "WA", "execution_time": "1819 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    if n == 2:\n        qc.cx(0, 1)\n        qc.cx(1, 0)\n        qc.cx(0, 1)\n    else:\n        # n>2 の場合\n        # 1. x_0 を x_{n-1} の位置に移動 (CX ゲートを使用)\n        qc.cx(0, n-1)\n        qc.cx(n-1, 0)\n        qc.cx(0, n-1)\n\n        # 2. x_1 から x_{n-2} を左に1ビットシフト (CX ゲートを使用)\n        for i in range(1, n-1):\n            qc.cx(i, i+1)\n            qc.cx(i+1, i)\n            qc.cx(i, i+1)\n\n    \n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 10, "result": "WA", "execution_time": "1663 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # x_{n-1} を x_0 の位置に移動\n    for i in range(n - 1):\n        qc.cx(n - 1, i)\n        qc.cx(i, n - 1)\n        qc.cx(n - 1, i)\n\n    # x_0 から x_{n-2} までのビットを右に 1 つずつシフト\n    for i in range(n - 2, 0, -1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)    \n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 11, "result": "WA", "execution_time": "1761 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # x_{n-1} を x_0 の位置に移動 \n    qc.x(n-1) \n    qc.cx(n-1,0) \n    qc.x(n-1) \n    qc.x(0) \n\n    # x_0 から x_{n-2} までのビットを右に 1 つずつシフト \n    for i in range(1,n): \n        qc.cx(i-1,i) \n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 12, "result": "WA", "execution_time": "1915 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 最後の量子ビットを保存するために一時的に古い値を保持する\n    for i in range(n - 1):\n        qc.cx(i, i + 1)  # 量子ビット間でCNOTゲートを使って状態を転送\n    \n    # 最後の量子ビットを最初に持ってくる\n    qc.cx(n - 1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 13, "result": "WA", "execution_time": "2019 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 最後の量子ビットを保存するために一時的に古い値を保持する\n    for i in range(n - 1):\n        qc.cx(i, i + 1)  # 量子ビット間でCNOTゲートを使って状態を転送\n    \n    # 最後の量子ビットを最初に持ってくる\n    qc.cx(n - 1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2F64113BE70F", "submission_order": 14, "result": "WA", "execution_time": "2127 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 最後の量子ビットを保存するために一時的に古い値を保持する\n    for i in range(n - 1):\n        qc.cx(i, i + 1)  # 量子ビット間でCNOTゲートを使って状態を転送\n    \n    # 最後の量子ビットを最初に持ってくる\n    qc.cx(n - 1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A2FDDDD77AD50", "submission_order": 1, "result": "AC", "execution_time": "2949 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tdef make(l, r):\n\t\tif r - l == 1:\n\t\t\treturn\n\t\tm = l + r >> 1\n\t\tmake(l, m)\n\t\tmake(m, r)\n\t\tqc.cx(l, m)\n\t\tqc.cx(m, l)\n\t\tqc.cx(l, m)\n\tmake(0, n)\n\treturn qc\n'''"}
{"problem": "QPC004_A4", "user": "A31A695DC7672", "submission_order": 1, "result": "WA", "execution_time": "1806 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    def _swap(i, j):\n        #qc.swap(i, j)\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n\n    curr = list(range(n))\n    while True:\n        need_replace = []\n\n        for idx in range(n):\n            if curr[idx] != (idx + 1) % n:\n                need_replace.append(idx)\n\n        for idx in range(0, len(need_replace), 2):\n            if idx+1 >= len(need_replace):\n                continue\n\n            a = need_replace[idx]\n            b = need_replace[idx + 1]\n            _swap(a, b)\n            curr[a], curr[b] = curr[b], curr[a]\n\n        if len(need_replace) == 0:\n            break\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A31A695DC7672", "submission_order": 2, "result": "AC", "execution_time": "1959 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    def _swap(i, j):\n        #qc.swap(i, j)\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n\n    curr = list(range(n))\n    while True:\n        need_replace = []\n\n        for idx in range(n):\n            if curr[idx] != (idx + n - 1) % n:\n                need_replace.append(idx)\n\n        for idx in range(0, len(need_replace), 2):\n            if idx+1 >= len(need_replace):\n                continue\n\n            a = need_replace[idx]\n            b = need_replace[idx + 1]\n            _swap(a, b)\n            curr[a], curr[b] = curr[b], curr[a]\n\n        if len(need_replace) == 0:\n            break\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A322D2B79FAAA", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(, n)):\n        qc.cx(i-1,i)\n        qc.cx(i-0,i-1)\n        qc.cx(i-1,i)  \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A322D2B79FAAA", "submission_order": 2, "result": "DLE", "execution_time": "2385 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(1, n)):\n        qc.cx(i-1,i)\n        qc.cx(i-0,i-1)\n        qc.cx(i-1,i)  \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A322D2B79FAAA", "submission_order": 3, "result": "RE", "execution_time": "1895 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    swap = np.array([1,0,0,0],\n                    [0,0,1,0],\n                    [0,1,0,0],\n                    [0,0,0,1])\n    for i in reversed(range(0, n)):\n        qc.append(UnitaryGate(swap),[i-1,i])\n        # qc.cx(i-0,i-1)\n        # qc.cx(i-1,i)  \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A322D2B79FAAA", "submission_order": 4, "result": "RE", "execution_time": "1812 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    swap = np.array([[1,0,0,0],\n                    [0,0,1,0],\n                    [0,1,0,0],\n                    [0,0,0,1]])\n    for i in reversed(range(0, n)):\n        qc.append(UnitaryGate(swap),[i-1,i])\n        # qc.cx(i-0,i-1)\n        # qc.cx(i-1,i)  \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A322D2B79FAAA", "submission_order": 5, "result": "RE", "execution_time": "2134 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    swap = np.array([[1,0,0,0],\n                    [0,0,1,0],\n                    [0,1,0,0],\n                    [0,0,0,1]])\n    for i in reversed(range(0, n)):\n        qc.append(Operator(swap),[i-1,i])\n        # qc.cx(i-0,i-1)\n        # qc.cx(i-1,i)  \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A322D2B79FAAA", "submission_order": 6, "result": "AC", "execution_time": "2543 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A3331B7981FE9", "submission_order": 1, "result": "DLE", "execution_time": "1582 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.cx(i, n - 1)      # Step 1: CNOT with control q_i and target q_{n-1}\n        qc.cx(n - 1, i)      # Step 2: CNOT with control q_{n-1} and target q_i\n        qc.cx(i, n - 1) \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A3331B7981FE9", "submission_order": 2, "result": "WA", "execution_time": "1794 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    half = n // 2\n\n    # Layer 1: For each pair, do the first CNOT.\n    for i in range(half):\n        qc.cx(i, n - i - 1)\n    \n    # Layer 2: For each pair, do the second CNOT.\n    for i in range(half):\n        qc.cx(n - i - 1, i)\n    \n    # Layer 3: For each pair, do the third CNOT.\n    for i in range(half):\n        qc.cx(i, n - i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A3331B7981FE9", "submission_order": 3, "result": "AC", "execution_time": "1945 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)  # Copy the content of q[i] into q[i+1] (which is 0)\n        qc.cx(i+1, i)  #\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A341177C52AB1", "submission_order": 1, "result": "TOE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n    qc.cx(i-1,i)\n    qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A386D9388A983", "submission_order": 1, "result": "DLE", "execution_time": "3000 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A386D9388A983", "submission_order": 2, "result": "AC", "execution_time": "2106 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        #qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A416745262925", "submission_order": 1, "result": "AC", "execution_time": "2111 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n // 2):\n        qc.cx(i, n - 1 - i)\n        qc.cx(n - 1 - i, i)\n        qc.cx(i, n - 1 - i)\n\n    for j in range((n - 1) // 2):\n        qc.cx(1 + j, n - 1 - j)\n        qc.cx(n - 1 - j, 1 + j)\n        qc.cx(1 + j, n - 1 - j)\n            \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A45E8AF2DC02F", "submission_order": 1, "result": "DLE", "execution_time": "2023 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if n-i-2 < 0:\n            break\n        qc.cx(n-i-2,n-i-1)\n        qc.cx(n-i-1, n-i-2)\n        qc.cx(n-i-2, n-i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A45E8AF2DC02F", "submission_order": 2, "result": "WA", "execution_time": "1765 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if n-i-2 < 0:\n            break\n        qc.cx(n-i-2,n-i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A45E8AF2DC02F", "submission_order": 3, "result": "AC", "execution_time": "2055 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if n-i-2 < 0:\n            break\n        qc.cx(n-i-2,n-i-1)\n        qc.cx(n-i-1,n-i-2)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 1, "result": "DLE", "execution_time": "1769 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # n qubitのn番目のqubitを0番目にスワップする、swapゲートを使わない実装\n    # Xn-1=0 の条件あり\n    for i in range(n-1, 0, -1):     \n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 2, "result": "DLE", "execution_time": "2123 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):     \n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 3, "result": "WA", "execution_time": "1925 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0, n-2):     \n        qc.cx(i,n-2)\n        qc.cx(n-2,i)\n        qc.cx(i,n-2)\n     \n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 4, "result": "WA", "execution_time": "1968 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0, n-1):     \n        qc.cx(i,n-1)\n        qc.cx(n-1,i)\n        qc.cx(i,n-1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 5, "result": "WA", "execution_time": "2010 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    qc.x(0)\n\n    for i in range(1, n-2):     \n        qc.cx(i,n-2)\n        qc.cx(n-2,i)\n        qc.cx(i,n-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 6, "result": "RE", "execution_time": "2057 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 7, "result": "DLE", "execution_time": "1794 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 8, "result": "WA", "execution_time": "1760 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.cx(0, n-1)\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 9, "result": "WA", "execution_time": "1887 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-1-i)\n        qc.cx(n-1-i, i)\n        qc.cx(i, n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A4B1337A6476E", "submission_order": 10, "result": "WA", "execution_time": "1847 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.cx(i, n-1-i)\n        qc.cx(n-1-i, i)\n        qc.cx(i, n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A58CC1AC39DA9", "submission_order": 1, "result": "DLE", "execution_time": "1849 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-i-1, n-i-2)\n        qc.cx(n-i-2, n-i-1)\n        qc.cx(n-i-1, n-i-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A58CC1AC39DA9", "submission_order": 2, "result": "WA", "execution_time": "1683 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-i-1, n-i-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A58CC1AC39DA9", "submission_order": 3, "result": "WA", "execution_time": "1829 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-i-1, n-i-2)\n        qc.cx(n-i-2, n-i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A58CC1AC39DA9", "submission_order": 4, "result": "AC", "execution_time": "2517 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-i-2, n-i-1)\n        qc.cx(n-i-1, n-i-2)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5998F29AB64B", "submission_order": 1, "result": "DLE", "execution_time": "1776 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef my_swap(qc, q1, q2):\n    qc.cx(q1, q2)\n    qc.cx(q2, q1)\n    qc.cx(q1, q2)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n    \tmy_swap(qc, i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5998F29AB64B", "submission_order": 2, "result": "AC", "execution_time": "2092 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef my_swap(qc, q1, q2):\n    qc.cx(q1, q2)\n    qc.cx(q2, q1)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n    \tmy_swap(qc, i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5A432871A3EA", "submission_order": 1, "result": "WA", "execution_time": "1780 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n-1)\n\n    for i in range(2, n):\n        # 1 ~ N-1까지 반복\n        at = n-i-1\n        qc.ccx(n-1, at, at+1)\n        qc.ccx(n-1, at+1, at)\n        qc.ccx(n-1, at, at+1)\n    \n    # qc가 1이면 0과 n-1을 swap\n    # qc가 0이면 swap하지 않음\n\n    qc.x(0)\n    qc.cx(0, n-1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5A432871A3EA", "submission_order": 2, "result": "DLE", "execution_time": "1556 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n):\n        # 1 ~ N-1까지 반복\n        at = n-i-1\n        qc.cx(at, at+1)\n        qc.cx(at+1, at)\n        qc.cx(at, at+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5A432871A3EA", "submission_order": 3, "result": "WA", "execution_time": "1711 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n-1)\n\n    for i in range(1, n):\n        # 1 ~ N-1까지 반복\n        at = n-i-1\n        qc.cx(at, at+1)\n        qc.cx(at+1, at)\n\n    qc.cx(n-1, 0)\n    qc.cx(0, n-1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5A432871A3EA", "submission_order": 4, "result": "WA", "execution_time": "1764 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n-1)\n\n    for i in range(1, n):\n        # 1 ~ N-1까지 반복\n        at = n-i-1\n        qc.cx(at, at+1)\n        qc.cx(at+1, at)\n\n    #qc.cx(n-1, 0)\n    #qc.cx(0, n-1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5A432871A3EA", "submission_order": 5, "result": "AC", "execution_time": "2542 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(1, n):\n        # 1 ~ N-1까지 반복\n        at = n-i-1\n        # at를 at+1로 밀기\n        qc.cx(at, at+1)\n        qc.cx(at+1, at)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5C3480530BC1", "submission_order": 1, "result": "WA", "execution_time": "2554 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply CNOT gates to perform the cyclic shift\n    for i in range(n - 1):\n        qc.cx(i, i + 1)  # Move x_i to x_(i+1)\n    \n    # Move the last qubit (which is always 0) to the first position\n    qc.cx(n - 1, 0)  # Move x_(n-1) to x_0\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5E4593EA1C98", "submission_order": 1, "result": "UGE", "execution_time": "1482 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef A3(n: int) -> QuantumCircuit:\n    def swap(n: int, qubit1: int, qubit2: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n \n        qc.cx(qubit1, qubit2)\n        qc.cx(qubit2, qubit1)\n        qc.cx(qubit1, qubit2)\n \n        return qc\n \n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n - 1)):\n        qc.compose(swap(n, i, i + 1), inplace=True)\n \n    return qc\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    A3_circuit = A3(n).to_instruction(label=\"A2\")\n    qc.compose(A3_circuit, inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5E4593EA1C98", "submission_order": 2, "result": "DLE", "execution_time": "1709 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef A3(n: int) -> QuantumCircuit:\n    def swap(n: int, qubit1: int, qubit2: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n \n        qc.cx(qubit1, qubit2)\n        qc.cx(qubit2, qubit1)\n        qc.cx(qubit1, qubit2)\n \n        return qc\n \n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n - 1)):\n        qc.compose(swap(n, i, i + 1), inplace=True)\n \n    return qc\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(A3(n), inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A5E4593EA1C98", "submission_order": 3, "result": "UGE", "execution_time": "1503 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef A3(n: int) -> QuantumCircuit:\n    def swap(n: int, qubit1: int, qubit2: int) -> QuantumCircuit:\n        qc = QuantumCircuit(n)\n \n        qc.cx(qubit1, qubit2)\n        qc.cx(qubit2, qubit1)\n        qc.cx(qubit1, qubit2)\n \n        return qc\n \n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n - 1)):\n        qc.compose(swap(n, i, i + 1), inplace=True)\n \n    return qc\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(A3(n).to_instruction(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A606272DCAC26", "submission_order": 1, "result": "RE", "execution_time": "1803 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc,i,j):\n        qc.cx(i,j)\n        qc.cx(j,i)\n        qc.cx(i,j)\n    for i in range(n//2):\n        swap(qc,2*i,2*i+1)\n    for j in range(n-(n%2==0),2,-2):\n        swap(qc,j,j-2)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A606272DCAC26", "submission_order": 2, "result": "RE", "execution_time": "1598 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> qt.QuantumCircuit:\n    qc = qt.QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc,i,j):\n        qc.cx(i,j)\n        qc.cx(j,i)\n        qc.cx(i,j)\n    for i in range(0,n-1,2):\n        swap(qc,i,i+1)\n    for j in range(n-1-(n%2==0),1,-2):\n        print(j,n)\n        swap(qc,j,j-2)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A606272DCAC26", "submission_order": 3, "result": "RE", "execution_time": "1681 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> qt.QuantumCircuit:\n    qc = qt.QuantumCircuit(n)\n    # Write your code here:\n    def sw(qc,i,j):\n        qc.cx(i,j)\n        qc.cx(j,i)\n        qc.cx(i,j)\n    for i in range(0,n-1,2):\n        sw(qc,i,i+1)\n    for j in range(n-1-(n%2==0),1,-2):\n        sw(qc,j,j-2)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A606272DCAC26", "submission_order": 4, "result": "AC", "execution_time": "2096 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def sw(qc,i,j):\n        qc.cx(i,j)\n        qc.cx(j,i)\n        qc.cx(i,j)\n    for i in range(0,n-1,2):\n        sw(qc,i,i+1)\n    for j in range(n-1-(n%2==0),1,-2):\n        sw(qc,j,j-2)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A61E4491E7FB4", "submission_order": 1, "result": "AC", "execution_time": "2758 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n - 1)):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6227312D0392", "submission_order": 1, "result": "WA", "execution_time": "1782 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6227312D0392", "submission_order": 2, "result": "AC", "execution_time": "2106 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6D6F94CA5422", "submission_order": 1, "result": "WA", "execution_time": "1845 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc, a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    rest = [*range(n)]\n    while rest:\n        newrest = []\n        for i in range(len(rest)//2):\n            a = rest[2*i]\n            b = rest[2*i+1]\n            rest.append(b)\n            swap(qc, a, b)\n        rest = newrest\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6D6F94CA5422", "submission_order": 2, "result": "WA", "execution_time": "1665 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc, a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    rest = [*range(n)]\n    while rest:\n        newrest = []\n        for i in range(len(rest)//2):\n            a = rest[2*i]\n            b = rest[2*i+1]\n            newrest.append(b)\n            swap(qc, a, b)\n        rest = newrest\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6D6F94CA5422", "submission_order": 3, "result": "WA", "execution_time": "1948 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc, a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    rest = [*range(n)]\n    while len(rest) != 1:\n        newrest = []\n        for i in range(len(rest)//2):\n            a = rest[2*i]\n            b = rest[2*i+1]\n            newrest.append(b)\n            swap(qc, a, b)\n        if len(rest)%2 == 1:\n            newrest.append(rest[-1])\n        rest = newrest\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6D6F94CA5422", "submission_order": 4, "result": "DLE", "execution_time": "1672 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc, a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    now = [*range(n)]\n    ans = [n-1] + [*range(n-1)]\n    while now != ans:\n        t = -1\n        for i in range(n):\n            if now[i] != ans[i]:\n                if t != -1:\n                    swap(qc, t, i)\n                    now[t],now[i] = now[i],now[t]\n                else:\n                    t = i \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6D6F94CA5422", "submission_order": 5, "result": "TLE", "execution_time": "3000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc, a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    now = [*range(n)]\n    ans = [n-1] + [*range(n-1)]\n    f = 1\n    while now != ans:\n        t = -1\n        for i in range(n)[::-1*f]:\n            if now[i] != ans[i]:\n                if t != -1:\n                    swap(qc, t, i)\n                    now[t],now[i] = now[i],now[t]\n                else:\n                    t = i \n        f *= -1\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6D6F94CA5422", "submission_order": 6, "result": "DLE", "execution_time": "1559 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def swap(qc, a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    now = [*range(n)]\n    ans = [n-1] + [*range(n-1)]\n    f = 1\n    while now != ans:\n        t = -1\n        if f:\n            for i in range(n):\n                if now[i] != ans[i]:\n                    if t != -1:\n                        swap(qc, t, i)\n                        now[t],now[i] = now[i],now[t]\n                    else:\n                        t = i\n        else:\n             for i in range(n-1,-1,-1):\n                if now[i] != ans[i]:\n                    if t != -1:\n                        swap(qc, t, i)\n                        now[t],now[i] = now[i],now[t]\n                    else:\n                        t = i\n        f ^= 1\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6DF521CC4636", "submission_order": 1, "result": "DLE", "execution_time": "1624 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6DF521CC4636", "submission_order": 2, "result": "RE", "execution_time": "1703 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.measure(n-1, 0)\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i+1).c_if(0, 1)\n        qc.cx(i+1, i).c_if(0, 1)\n        qc.cx(i, i+1).c_if(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6DF521CC4636", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nfrom qiskit.visualization import *\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.measure(n-1, 0)\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i+1).c_if(0, 1)\n        qc.cx(i+1, i).c_if(0, 1)\n        qc.cx(i, i+1).c_if(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6DF521CC4636", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.measure(n-1, 0)\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i+1).c_if(0, 1)\n        qc.cx(i+1, i).c_if(0, 1)\n        qc.cx(i, i+1).c_if(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6DF521CC4636", "submission_order": 5, "result": "WA", "execution_time": "1651 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef swap3(qc: QuantumCircuit, q1: int, q2: int):\n    \"\"\"\n    QiskitのSwapGateは禁止なので、\n    SWAP(q1,q2) を CNOT×3 に手動分解する。\n      - CNOT(q1->q2)\n      - CNOT(q2->q1)\n      - CNOT(q1->q2)\n    \"\"\"\n    qc.cx(q1, q2)\n    qc.cx(q2, q1)\n    qc.cx(q1, q2)\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # リング上の辺 E_i = (i, i-1 mod n)\n    # Layer0: i even\n    # Layer1: i odd\n    layer0 = []\n    layer1 = []\n    for i in range(n):\n        e = (i, (i - 1) % n)\n        if i % 2 == 0:\n            layer0.append(e)\n        else:\n            layer1.append(e)\n\n    # --- 第1層: 偶数 i の辺を並列SWAP ---\n    for (s, t) in layer0:\n        swap3(qc, s, t)\n\n    # --- 第2層: 奇数 i の辺を並列SWAP ---\n    for (s, t) in layer1:\n        swap3(qc, s, t)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6DF521CC4636", "submission_order": 6, "result": "WA", "execution_time": "1793 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef swap_adj(qc: QuantumCircuit, i: int, j: int):\n    \"\"\"\n    隣接SWAPを CNOT×3 で分解。\n    ただし i+1 = j を想定している。\n    \"\"\"\n    qc.cx(i, j)\n    qc.cx(j, i)\n    qc.cx(i, j)\n\ndef solve(n: int) -> QuantumCircuit:\n    \"\"\"\n    入力状態 |x0 x1 ... x_{n-2} 0> を\n    出力状態 |0 x0 x1 ... x_{n-2}> に写す回路を、\n    SwapGate禁止＆深さ<=20 で実装する。\n    \"\"\"\n    qc = QuantumCircuit(n)\n\n    # 右端のビット(=qubit n-1)を先頭(=qubit 0)へバブル移動\n    # それには (n-1) 回の「隣接SWAP(q[i], q[i+1])」が必要。\n    # しかし単純に直列実行すると深さが 3*(n-1) になってしまう。\n    #\n    # 下記では “odd-evenトランスフォーム” の要領で、ペアが重ならないSWAPを\n    # できるだけ同時並行に行い、深さを削減している。\n    #\n    # おおまかに:\n    #   round 1: すべての偶数ペア (0,1), (2,3), (4,5),...\n    #   round 2: すべての奇数ペア (1,2), (3,4), (5,6),...\n    # を繰り返し、右端ビットを順次左へシフト。\n\n    # ここでは “n-1” ステップを繰り返せば必ず最右ビットが先頭に来る\n    # (実際はバブル移動しながら全体を右回転する)。\n    # 各ステップは2サブラウンド(偶数ペアと奇数ペア)に分かれる。\n    # 1サブラウンド内は並列実行できるので、SWAP分の深さが3だけ加わる。\n\n    for step in range(n-1):\n        # サブラウンド1: 偶数ペアのSWAPを並列に\n        for i in range(0, n-1, 2):\n            swap_adj(qc, i, i+1)\n        # サブラウンド2: 奇数ペアのSWAPを並列に\n        for i in range(1, n-1, 2):\n            swap_adj(qc, i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6DF521CC4636", "submission_order": 7, "result": "AC", "execution_time": "2051 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n        \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A6E2501F2434E", "submission_order": 1, "result": "AC", "execution_time": "2839 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n : int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    #隣と入れ替える\n    for i in range(int(n/2)):\n        qc.cx(2*i,2*i+1)\n        qc.cx(2*i+1,2*i)\n        qc.cx(2*i,2*i+1)\n    if(n%2 == 0):\n        n-=1\n\n    for i in range(n-1,0,-2):\n        qc.cx(i,i-2)\n        qc.cx(i-2,i)\n        qc.cx(i,i-2)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A72E958C6C42B", "submission_order": 1, "result": "AC", "execution_time": "2076 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in reversed(range(n-1)):\n        qc.cx(_,_+1)\n        qc.cx(_+1,_)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A753F7E0B4BF6", "submission_order": 1, "result": "RE", "execution_time": "1477 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n,1,-1):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A753F7E0B4BF6", "submission_order": 2, "result": "AC", "execution_time": "1754 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7926B7C9A0E0", "submission_order": 1, "result": "AC", "execution_time": "1806 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(n - i - 2, n - i - 1)\n        qc.cx(n - i - 1, n - i - 2)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n    qc.cx(n-1, i)\n    qc.cx(i, n-1)\n    qc.cx(n-1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 2, "result": "DLE", "execution_time": "1647 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.cx(n-1, i)\n        qc.cx(i, n-1)\n        qc.cx(n-1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 3, "result": "WA", "execution_time": "1713 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.cx(n-2-i, n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 4, "result": "WA", "execution_time": "1639 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-2):\n        qc.cx(n-2-i, n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 5, "result": "WA", "execution_time": "1763 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-2):\n        qc.cx(n-2-i, n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 6, "result": "WA", "execution_time": "1949 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-2):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 7, "result": "WA", "execution_time": "1944 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-2):\n        qc.cx(i+1, i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 8, "result": "WA", "execution_time": "1777 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.cx(i+1, i)\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7AB6B499FA95", "submission_order": 9, "result": "AC", "execution_time": "2237 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.cx(n-i-2, n-i-1)\n        qc.cx(n-i-1, n-i-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7B09671EF61A", "submission_order": 1, "result": "RE", "execution_time": "2497 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(2*n-1)):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A7B09671EF61A", "submission_order": 2, "result": "AC", "execution_time": "2421 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A8330D8DFDE03", "submission_order": 1, "result": "AC", "execution_time": "1911 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n//2):\n        qc.cx(i, n - 1 - i)\n        qc.cx(n - 1 - i, i)\n        qc.cx(i, n - 1 - i)\n    for i in range(1, n//2 + n%2):\n        qc.cx(i, n - i)\n        qc.cx(n - i, i)\n        qc.cx(i, n - i)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A853B6121B2E6", "submission_order": 1, "result": "AC", "execution_time": "1875 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-i-2, n-i-1)\n        qc.cx(n-i-1, n-i-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A8D7148F00ADD", "submission_order": 1, "result": "WA", "execution_time": "1744 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n-2, 0, -1):\n        qc.ccx(n-1, i-1, i)\n        qc.ccx(n-1, i, i-1)\n        qc.ccx(n-1, i-1, i)\n\n    # 0が1でn-1が0の時だけ交換\n    qc.x(n-1)         # n-1を反転（0→1, 1→0）\n    qc.cx(0, n-1)    # 0が1ならn-1を反転\n    qc.cx(n-1, 0)    # n-1が1なら0を反転\n    qc.x(n-1)         # n-1を元に戻す\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A8E870BC59177", "submission_order": 1, "result": "AC", "execution_time": "2098 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n-1):\n        j = n-1-i\n        k = n-2-i\n        qc.cx(k,j)\n        qc.cx(j,k)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A9401218C2165", "submission_order": 1, "result": "DLE", "execution_time": "1864 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def cnot_swap(qc, q1, q2):\n        qc.cx(q1, q2)\n        qc.cx(q2, q1)\n        qc.cx(q1, q2)\n\n    for i in range(n-1):\n        cnot_swap(qc, 0, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A9401218C2165", "submission_order": 2, "result": "WA", "execution_time": "1754 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    def cnot_swap(qc, q1, q2):\n        qc.cx(q2, q1)\n        qc.cx(q1, q2)\n\n    for i in range(n-1):\n        cnot_swap(qc, 0, i+1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A9401218C2165", "submission_order": 3, "result": "WA", "execution_time": "1912 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1):\n        qc.h(n-i-2)\n        qc.cx(n-i-2, n-i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A94E80BD00F10", "submission_order": 1, "result": "AC", "execution_time": "2891 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    def swap(a,b):\n    \tqc.cx(a,b)\n    \tqc.cx(b,a)\n          \t\n    for i in range(n-1)[::-1]:\n    \tswap(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "A9B4B5279E210", "submission_order": 1, "result": "AC", "execution_time": "2566 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    def swap(a, b):\n        qc.cx(a, b)\n        qc.cx(b, a)\n        qc.cx(a, b)\n    \n    # Write your code here:\n    def cyc(L, R):\n        if R - L == 1:\n            return\n        mid = (L + R) // 2\n        swap(mid - 1, R - 1)\n        cyc(L, mid)\n        cyc(mid, R)\n\n    cyc(0, n)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AA31151CC9ECA", "submission_order": 1, "result": "AC", "execution_time": "1948 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-1,0,-1):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAB378C5A3EF3", "submission_order": 1, "result": "AC", "execution_time": "2207 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2,-1,-1):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AABC56EBA1CD2", "submission_order": 1, "result": "AC", "execution_time": "2047 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n        #qc.cx(i-1, i)\n \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 1, "result": "DLE", "execution_time": "1760 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 2, "result": "WA", "execution_time": "1820 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 3, "result": "RE", "execution_time": "1679 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 4, "result": "WA", "execution_time": "2497 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n    \n    qc.cx(n - 1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 5, "result": "RE", "execution_time": "1517 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, i + 1)\n    \n    qc.cx(n - 1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 6, "result": "WA", "execution_time": "1590 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        qc.cx(i, i + 1)\n    \n    qc.cx(n - 1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 7, "result": "DLE", "execution_time": "2138 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 8, "result": "WA", "execution_time": "2386 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def tdswap(QC,qi):#qi=0~n-2\n        qc.cx(qi+1,qi)\n        qc.cx(qi,qi+1)\n\n    for i in range(0,n-1):\n        tdswap(qc,i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 9, "result": "WA", "execution_time": "2245 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def tdswap(QC,qi):#qi=0~n-2\n        qc.cx(qi+1,qi)\n        qc.cx(qi,qi+1)\n\n    for i in range(n-2,-1, -1):\n        tdswap(qc,i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 10, "result": "WA", "execution_time": "1980 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def tdswap(QC,qi):#qi=0~n-2\n        qc.cx(qi,qi+1)\n        qc.cx(qi+1,qi)\n\n    for i in range(0,n-1):\n        tdswap(qc,i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAC2A33C0BAC8", "submission_order": 11, "result": "AC", "execution_time": "2148 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def tdswap(QC,qi):#qi=0~n-2\n        qc.cx(qi,qi+1)\n        qc.cx(qi+1,qi)\n\n    for i in range(n-2,-1,-1):\n        tdswap(qc,i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AAEFB26697847", "submission_order": 1, "result": "AC", "execution_time": "1895 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n - 1)\n    for i in range(n - 2, -1, -1):\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AB7DBF9319832", "submission_order": 1, "result": "WA", "execution_time": "1787 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AB7DBF9319832", "submission_order": 2, "result": "AC", "execution_time": "2182 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AB8A5DF0518FC", "submission_order": 1, "result": "DLE", "execution_time": "2696 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in reversed(range(n-1)):\n        i_first=i\n        i_second=(i+1) % n\n        qc.cx(i_first, i_second)\n        qc.cx(i_second, i_first)\n        qc.cx(i_first, i_second)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AB8A5DF0518FC", "submission_order": 2, "result": "AC", "execution_time": "2201 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in reversed(range(n-1)):\n        i_first=i\n        i_second=(i+1) % n\n        qc.cx(i_first, i_second)\n        qc.cx(i_second, i_first)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ABAA1B789E683", "submission_order": 1, "result": "AC", "execution_time": "1978 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n - 1):\n        index = n - i - 1\n        qc.cx(index - 1, index)\n        qc.cx(index, index - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ABBA7DB5DA7B2", "submission_order": 1, "result": "WA", "execution_time": "2011 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef swap(qc: QuantumCircuit, a: int, b: int) -> None:\n    qc.cx(a, b)\n    qc.cx(b, a)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n - 1, 0, -1):\n        swap(qc, i, i - 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ABBA7DB5DA7B2", "submission_order": 2, "result": "AC", "execution_time": "2273 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef swap(qc: QuantumCircuit, a: int, b: int) -> None:\n    qc.cx(a, b)\n    qc.cx(b, a)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n - 1, 0, -1):\n        swap(qc, i - 1, i)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ABD16D4296A3F", "submission_order": 1, "result": "WA", "execution_time": "2125 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2,-1,-1):\n        qc.iswap(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ABD16D4296A3F", "submission_order": 2, "result": "AC", "execution_time": "2240 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n-2,-1,-1):\n        qc.dcx(i,i+1)\n        qc.cx(i,i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ABD7F27330D26", "submission_order": 1, "result": "AC", "execution_time": "1927 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# import matplotlib.pyplot\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(0, n-1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n \n    return qc\n\n# solve(3).draw(\"mpl\")\n'''"}
{"problem": "QPC004_A4", "user": "AC5224FDC038B", "submission_order": 1, "result": "WA", "execution_time": "1868 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2, -1):\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AC5224FDC038B", "submission_order": 2, "result": "WA", "execution_time": "1713 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2, -1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AC5224FDC038B", "submission_order": 3, "result": "AC", "execution_time": "2347 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2, -1, -1):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ACBC09138DA91", "submission_order": 1, "result": "AC", "execution_time": "2212 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1,n,2):\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n        qc.cx(i-1,i)\n    for i in range(((n-1)//2)*2,1,-2):\n        qc.cx(i-2,i)\n        qc.cx(i,i-2)\n        qc.cx(i-2,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ACC19B4C15164", "submission_order": 1, "result": "WA", "execution_time": "1739 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ACC19B4C15164", "submission_order": 2, "result": "WA", "execution_time": "1763 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(1, n-1):\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ACC19B4C15164", "submission_order": 3, "result": "WA", "execution_time": "1631 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(n-1)\n    for i in range(1, n-1):\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ACC473061E56A", "submission_order": 1, "result": "AC", "execution_time": "2450 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for q in range(n-1, 0, -1):\n        qc.cx(q-1, q)\n        qc.cx(q, q-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ACCECCD1768A0", "submission_order": 1, "result": "AC", "execution_time": "2304 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 0, -1):\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 1, "result": "RE", "execution_time": "2342 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Apply the cyclic shift only if x_(n-1) = 0 (controlled on qubit n-1 being |0⟩)\n    for i in range(n - 2, -1, -1):\n        qc.ccx(n - 1, i, i + 1)  # Controlled shift using CCX\n        qc.cx(i + 1, i)\n        qc.ccx(n - 1, i, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 2, "result": "WA", "execution_time": "1715 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # For n=2 case, we need a CNOT gate to handle |10⟩ → |01⟩\n    # For larger n, we need to shift all bits right cyclically\n    \n    # Since xₙ₋₁ = 0 is guaranteed, we can use this fact\n    # We can propagate values using CNOTs\n    \n    # Propagate values from right to left using CNOTs\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n    \n    # The leftmost qubit will be 0 (given constraint)\n    # so we don't need to handle that case\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 3, "result": "WA", "execution_time": "2121 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Implement the cyclic shift logic\n    # Condition: x_(n-1) = 0, meaning last qubit is 0\n    for i in range(n - 1, 0, -1):  \n        qc.cx(i - 1, i)  # Perform CNOTs to shift\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 4, "result": "WA", "execution_time": "1893 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Implement the cyclic shift logic\n    # Condition: x_(n-1) = 0, meaning last qubit is 0\n    for i in range(n - 1, 0, -1):  \n        qc.cx(i - 1, i)  # Perform CNOTs to shift\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 5, "result": "WA", "execution_time": "2432 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # For cyclic shift when last qubit (xₙ₋₁) = 0\n    # We can use CNOT gates to implement the shift\n    \n    # Apply CNOT gates in reverse order to shift the bits\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    \n    # Apply CNOT gates in forward order to complete the transformation\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n        \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 6, "result": "WA", "execution_time": "2134 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Perform the cyclic shift\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n    \n    # Swap the first and last qubit states\n    qc.cx(n-1, 0)\n    \n    return qc\n\n# Example usage:\nn = 2\nqc = solve(n)\nprint(qc)\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 7, "result": "WA", "execution_time": "1875 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # For n qubits, we need to perform a controlled cyclic shift\n    # First, connect adjacent qubits with CNOT to propagate values\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    \n    # The last qubit now holds the shifted value\n    # We need to clear the intermediate states\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n    \n    # Finally, connect first and last qubit to complete the cycle\n    qc.cx(n-1, 0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 8, "result": "WA", "execution_time": "1854 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Perform the cyclic shift\n    for i in range(n-1):\n        qc.cx(i, i+1)  # CNOT from qubit i to qubit i+1\n    \n    # Handle the last qubit shifting to the first position\n    qc.cx(n-1, 0)\n    \n    return qc\n\n# Example usage:\nn = 2\nqc = solve(n)\nprint(qc)\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 9, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nffrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 10, "result": "WA", "execution_time": "1728 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\r\n\r\ndef solve(n: int) -> QuantumCircuit:\r\n    qc = QuantumCircuit(n)\r\n    \r\n    # Perform the cyclic shift\r\n    for i in range(n-1, 0, -1):\r\n        qc.cx(i-1, i)\r\n    \r\n    # Move the last qubit to the first position\r\n    qc.cx(n-1, 0)\r\n    \r\n    return qc\r\n\r\n# Example usage:\r\n# qc = solve(2)\r\n# print(qc)\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 11, "result": "WA", "execution_time": "1765 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\r\n\r\ndef solve(n: int) -> QuantumCircuit:\r\n    qc = QuantumCircuit(n)\r\n    \r\n    # Perform the cyclic shift\r\n    # Step 1: Move the last qubit to the first position\r\n    for i in range(n-1, 0, -1):\r\n        qc.cx(i-1, i)  # CNOT from qubit i-1 to qubit i\r\n    \r\n    # Step 2: Move the last qubit to the first position\r\n    qc.cx(n-1, 0)  # CNOT from qubit n-1 to qubit 0\r\n    \r\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 12, "result": "WA", "execution_time": "1798 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\r\n\r\ndef solve(n: int) -> QuantumCircuit:\r\n    qc = QuantumCircuit(n)\r\n    \r\n    # We only perform the cyclic shift when the last qubit (n-1) is 0\r\n    # To achieve this, we'll first apply X gate to the last qubit\r\n    qc.x(n-1)\r\n    \r\n    # Now we can use the last qubit as control for our cyclic shift\r\n    # We need to move each bit to its new position when control is 1\r\n    # This effectively performs the shift when original last bit was 0\r\n    for i in range(n-1):\r\n        qc.cx(i, (i+1)%n)\r\n    \r\n    # Apply CNOTs in reverse order to clean up intermediate states\r\n    for i in range(n-2, -1, -1):\r\n        qc.cx(i, (i+1)%n)\r\n    \r\n    # Finally, revert the X gate on the last qubit\r\n    qc.x(n-1)\r\n    \r\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 13, "result": "WA", "execution_time": "1969 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\r\n\r\ndef solve(n: int) -> QuantumCircuit:\r\n    qc = QuantumCircuit(n)\r\n    \r\n    # Perform the cyclic shift\r\n    # Step 1: Move the last qubit to the first position\r\n    for i in range(n-1, 0, -1):\r\n        qc.cx(i-1, i)  # CNOT from qubit i-1 to qubit i\r\n    \r\n    # Step 2: Move the last qubit to the first position\r\n    qc.cx(n-1, 0)  # CNOT from qubit n-1 to qubit 0\r\n    \r\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AD99954736B70", "submission_order": 14, "result": "WA", "execution_time": "1856 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\r\n\r\ndef solve(n: int) -> QuantumCircuit:\r\n    qc = QuantumCircuit(n)\r\n    \r\n    # We want to shift only when last qubit is 0\r\n    # So we'll use its inverse (1) as control\r\n    qc.x(n-1)\r\n    \r\n    # For each pair of qubits that need to be potentially swapped\r\n    for i in range(n-1):\r\n        next_i = (i + 1) % n\r\n        \r\n        # Controlled-CNOT (CNOT controlled by last qubit)\r\n        qc.cx(n-1, i)\r\n        qc.cx(i, next_i)\r\n        qc.cx(n-1, i)\r\n    \r\n    # Restore the last qubit\r\n    qc.x(n-1)\r\n    \r\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ADC7C03F5E011", "submission_order": 1, "result": "DLE", "execution_time": "2060 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(i, n-1)\n        qc.cx(n-1, i)\n        qc.cx(i, n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ADC7C03F5E011", "submission_order": 2, "result": "RE", "execution_time": "1871 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i, n-1)\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "ADD617AE5F914", "submission_order": 1, "result": "WA", "execution_time": "1621 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n        qc.cx(i,i+1)\n        qc.cx(i+1,i)\n        qc.cx(i,i+1)\n    \n    qc.reset(n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE011F31FF504", "submission_order": 1, "result": "WA", "execution_time": "1747 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-2):\n        qc.cx(0, i + 1)\n        qc.cx(i+1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE011F31FF504", "submission_order": 2, "result": "DLE", "execution_time": "1803 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n        qc.cx(i + 1, 0)\n        qc.cx(0, i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE011F31FF504", "submission_order": 3, "result": "RE", "execution_time": "1704 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2):\n        qc.cx(0, i + 1)\n        qc.cx(i + 1, 0)\n        qc.cx(0, i + 1)\n    qc.cx(0, n)\n    qc.cx(n-1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE011F31FF504", "submission_order": 4, "result": "WA", "execution_time": "1842 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 2):\n        qc.cx(0, i + 1)\n        qc.cx(i + 1, 0)\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE7FB514FC07F", "submission_order": 1, "result": "WA", "execution_time": "1837 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-1-i, n-2-i)\n        qc.cx(n-2-i, n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE7FB514FC07F", "submission_order": 2, "result": "AC", "execution_time": "1876 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.cx(n-2-i, n-1-i)\n        qc.cx(n-1-i, n-2-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE9CEDB5FAB12", "submission_order": 1, "result": "RE", "execution_time": "1919 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.measure(n-1, 0)\n        last = n - 1 - i\n        qc.cx(last - 1, last)\n        qc.cx(last, last - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE9CEDB5FAB12", "submission_order": 2, "result": "RE", "execution_time": "1831 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.measure(n-1, 0)\n        qc.reset(n-1)\n        last = n - 1 - i\n        qc.cx(last - 1, last)\n        qc.cx(last, last - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE9CEDB5FAB12", "submission_order": 3, "result": "WA", "execution_time": "2056 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.reset(n-1)\n        last = n - 1 - i\n        qc.cx(last - 1, last)\n        qc.cx(last, last - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE9CEDB5FAB12", "submission_order": 4, "result": "WA", "execution_time": "2022 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.reset(n-1)\n        last = n - 1 - i\n        qc.cx(last - 1, last)\n        qc.cx(last, last - 1)\n        qc.cx(last - 1, last)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE9CEDB5FAB12", "submission_order": 5, "result": "WA", "execution_time": "1768 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.reset(n-1)\n    for i in range(n-1):\n        last = n - 1 - i\n        qc.cx(last - 1, last)\n        qc.cx(last, last - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE9CEDB5FAB12", "submission_order": 6, "result": "WA", "execution_time": "1756 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.reset(n-1)\n    for i in range(n-1, 0, -1):\n        qc.cx(i - 1, i)\n        qc.cx(i, i - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE9CEDB5FAB12", "submission_order": 7, "result": "WA", "execution_time": "1725 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i - 1, i)\n        qc.cx(i, i - 1)\n        qc.cx(i - 1, i)\n    qc.reset(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AE9CEDB5FAB12", "submission_order": 8, "result": "AC", "execution_time": "1899 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.cx(i - 1, i)\n        qc.cx(i, i - 1)\n \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 1, "result": "WA", "execution_time": "1996 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n    \n    for i in range(n-2, 0, -1):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 2, "result": "WA", "execution_time": "1771 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)  \n    \n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i) \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 3, "result": "WA", "execution_time": "1705 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.cx(i, i + 1)  \n    qc.measure_all() \n    \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 4, "result": "WA", "execution_time": "1722 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n )\n    for i in range(n-1):\n        qc.cx(i, i+1) \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 5, "result": "WA", "execution_time": "1761 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n )\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1) \n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 6, "result": "DLE", "execution_time": "1679 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n )\n    \n    i = 0\n    j = n - 1\n    \n    while i < j:\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n        \n\n        i += 1\n        \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 7, "result": "WA", "execution_time": "1566 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n )\n    \n    i = 0\n    j = n - 1\n    \n    while i < j:\n        qc.cx(i, j)\n        qc.cx(j, i)\n        \n\n        i += 1\n        \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 8, "result": "WA", "execution_time": "1977 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n )\n\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    \n    qc.cx(n-1, 0)\n        \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 9, "result": "DLE", "execution_time": "1602 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n )\n    \n    i = 0\n    j = n - 1\n    \n    while i < j:\n        qc.cx(i, j)\n        qc.cx(j, i)\n        qc.cx(i, j)\n        \n\n        i += 1\n        \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AEB2C503CA056", "submission_order": 10, "result": "WA", "execution_time": "1593 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n )\n    \n    for i in range(n):\n        qc.h(i)\n    \n    for i in range(n-1, 0, -1):\n        qc.cz(i, i-1)  \n  \n    for i in range(n):\n        qc.h(i)\n    \n    return qc\n        \n\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AF57D7937E6CA", "submission_order": 1, "result": "DLE", "execution_time": "1834 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for _ in range(n-2,-1,-1):\n        qc.cx(_,_+1)\n        qc.cx(_+1,_)\n        qc.cx(_,_+1)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AF57D7937E6CA", "submission_order": 2, "result": "AC", "execution_time": "2483 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n - 1)):\n        qc.cx(i,i+1)\n    for i in reversed(range(n - 1)):\n        qc.cx(i+1,i)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AFFDE69566BB0", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for  in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n    return qc\n'''"}
{"problem": "QPC004_A4", "user": "AFFDE69566BB0", "submission_order": 2, "result": "AC", "execution_time": "2209 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 1, "result": "WA", "execution_time": "1750 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(0, n-1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 2, "result": "WA", "execution_time": "1810 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.cx(0, n-1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 3, "result": "WA", "execution_time": "1990 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, -1, -1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 4, "result": "WA", "execution_time": "2126 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 5, "result": "WA", "execution_time": "1910 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n                \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 6, "result": "RE", "execution_time": "1503 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if i == 0:\n            qc.x(0)\n        else:\n            # Apply an (i)-controlled X gate with controls qubits [0, 1, ..., i-1] and target qubit i.\n            qc.mcx(list(range(i)), i, mode='gray') \n                \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 7, "result": "RE", "execution_time": "1502 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        if i == 0:\n            qc.x(0)\n        else:\n            # Apply an (i)-controlled X gate with controls qubits [0, 1, ..., i-1] and target qubit i.\n            qc.mcx(list(range(i)), i, mode='gray') \n                \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 8, "result": "WA", "execution_time": "1661 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # 1. すべてのビットを反転 (Xゲート)\n    qc.x(range(n))\n    \n    # 2. +1 の加算回路 (Ripple-Carry Adder の簡易バージョン)\n    carry = 1  # 最下位ビットからキャリーを伝播させる\n    for i in range(n):\n        qc.cx(i, carry)  # i番目のビットにキャリーを伝播\n        carry = i  # 次のキャリー\n    \n    # 3. すべてのビットを再度反転\n    qc.x(range(n))\n                \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A02B3CB5A26B5", "submission_order": 9, "result": "RE", "execution_time": "1506 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    # Step 1. Invert every qubit.\n    qc.x(range(n))\n    \n    # Step 2. Add 1 modulo 2^n.\n    # To add a constant, it suffices to switch to the Fourier basis,\n    # apply appropriate phase shifts, then transform back.\n    #\n    # (a) Apply the Quantum Fourier Transform.\n    qc.append(QFT(n, do_swaps=True).to_gate(), range(n))\n    \n    # (b) In the Fourier basis, adding 1 is diagonal.\n    # For a state |y⟩ we must apply the phase exp(-2πi·y/2^n).\n    # Since y = Σ_{j=0}^{n-1} y_j 2^j, these phases can be applied\n    # as single-qubit phase gates on each qubit.\n    for j in range(n):\n        angle = -2 * math.pi / (2 ** (j+1))\n        qc.p(angle, j)\n    \n    # (c) Apply the inverse QFT.\n    qc.append(QFT(n, do_swaps=True).inverse().to_gate(), range(n))\n    \n    # Step 3. Invert every qubit again.\n    qc.x(range(n))\n                \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 1, "result": "WA", "execution_time": "1668 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 2, "result": "WA", "execution_time": "1786 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    for i in range(n-2):\n        qc.cx(i+1,i+2)\n        qc.cx(i,i+1)\n    qc.cx(n-2,n-1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 3, "result": "WA", "execution_time": "1811 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n-1)\n    for i in range(n-2):\n        qc.cx(n-i-2,n-i-3)\n        qc.cx(n-i-1,n-i-2)\n    qc.cx(1,0)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 4, "result": "WA", "execution_time": "1780 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n-1)\n    for i in reversed(range(2,n)):\n        qc.cx(i-1,i-2)\n        qc.cx(i,i-1)\n    qc.cx(1,0)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 5, "result": "WA", "execution_time": "1897 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n-1)\n    for i in reversed(range(2,n)):\n        qc.cx(i,i-1)\n    qc.cx(1,0)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 6, "result": "RE", "execution_time": "1606 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    fg=False\n    for i in reversed(range(n)):\n        if qc(i):\n            fg=True\n        qc.x(i)\n        if fg:\n            break\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 7, "result": "RE", "execution_time": "1670 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx([0,i],list(range(i+1)))\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 8, "result": "RE", "execution_time": "1701 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx([0,i],0)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 9, "result": "DLE", "execution_time": "1734 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    for i in reversed(range(1,n)):\n        qc.mcx(list(range(i)),i)\n    for i in range(1,n):\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 10, "result": "WA", "execution_time": "1682 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    for i in reversed(range(2,n)):\n        qc.mcx(list(range(i)),i)\n    qc.cx(0,1)\n    for i in range(2,n):\n        qc.x(i)\n    \n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A04CD095EBE6B", "submission_order": 11, "result": "AC", "execution_time": "2014 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx(list(range(i)),i)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A0558AE086803", "submission_order": 1, "result": "WA", "execution_time": "2066 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # We will decrement the value in the little-endian format\n    # We need to flip bits until we find a 0 to turn into a 1\n    for i in range(n):\n        # Flip the i-th qubit\n        qc.x(i)  # Prepare the qubit to be flipped\n        \n        # Apply a series of CNOT gates to handle the carry\n        if i < n - 1:\n            qc.cx(i, i + 1)  # CNOT from i to i+1\n        qc.x(i)  # Flip back the i-th qubit\n    \n    # The last qubit needs to be flipped to handle the wrap-around case\n    qc.x(n - 1)  # Prepare the last qubit to be flipped\n    for i in range(n - 1):\n        qc.cx(i, n - 1)  # CNOT from i to the last qubit\n    qc.x(n - 1)  # Flip back the last qubit\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A09936EFB94B6", "submission_order": 1, "result": "WA", "execution_time": "1924 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n - 1):\n        qc.append(XGate().control(1, ctrl_state=\"0\"), [i, i + 1])\n\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A09936EFB94B6", "submission_order": 2, "result": "AC", "execution_time": "2205 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\"\"\"\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # qc.x(0)\n    # qc.x(1)\n    # Write your code here:\n\n    for i in range(n, 1, -1):\n        qc.append(XGate().control(i-1, ctrl_state=\"0\" * (i-1)), range(i))\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A11B3B8921624", "submission_order": 1, "result": "WA", "execution_time": "2226 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(1, n)): \n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A11B3B8921624", "submission_order": 2, "result": "WA", "execution_time": "1766 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(1, n)): \n        qc.mcx(list(range(i)), i)\n \n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A11B3B8921624", "submission_order": 3, "result": "AC", "execution_time": "2632 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n \n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A124C87FC9690", "submission_order": 1, "result": "RE", "execution_time": "1614 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n, 0, -1):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n \n    return qc.inverse()\n'''"}
{"problem": "QPC004_A5", "user": "A124C87FC9690", "submission_order": 2, "result": "AC", "execution_time": "2409 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n-1, 0, -1):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n \n    return qc.inverse()\n'''"}
{"problem": "QPC004_A5", "user": "A13A59F12F17A", "submission_order": 1, "result": "WA", "execution_time": "1752 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n - 1)\n    # Write your code here:\n    for i in reversed(range(1, n)):\n        qc.cx(i, i - 1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A13A59F12F17A", "submission_order": 2, "result": "WA", "execution_time": "1556 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cx(i - 1, i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A13A59F12F17A", "submission_order": 3, "result": "WA", "execution_time": "1731 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    # Write your code here:\n    for i in range(1, n):\n        qc.cx(i, i - 1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A13FF9A90EB9F", "submission_order": 1, "result": "AC", "execution_time": "2244 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx(list(range(i)),i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A1AA6B7887115", "submission_order": 1, "result": "WA", "execution_time": "1787 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.mcx(list(range(n-1)),n-1)\n    qc.x(range(n-1))\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A1AA6B7887115", "submission_order": 2, "result": "WA", "execution_time": "1837 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.mcx(list(range(n-1)),n-1)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A1AA6B7887115", "submission_order": 3, "result": "WA", "execution_time": "1815 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.mcx(list(range(n-1)),n-1)\n    qc.x(range(n))\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A1E78B1A9C367", "submission_order": 1, "result": "WA", "execution_time": "1748 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A1E78B1A9C367", "submission_order": 2, "result": "AC", "execution_time": "2064 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx(list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A23B5E53A24DB", "submission_order": 1, "result": "WA", "execution_time": "1640 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A23B5E53A24DB", "submission_order": 2, "result": "WA", "execution_time": "1746 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(n-1, 0, -1):\n        control_bits = list(range(i, n))\n        qc.mcx(control_bits, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A23B5E53A24DB", "submission_order": 3, "result": "WA", "execution_time": "1684 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(n-1, 0, -1):\n        control_bits = list(range(i, n))\n        qc.mcx(control_bits, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A23B5E53A24DB", "submission_order": 4, "result": "WA", "execution_time": "1575 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 初期状態に基づいて量子減算器を実装\n    for i in range(n):\n        qc.x(i)  # 全ての量子ビットを反転\n\n    for i in range(n - 1, 0, -1):\n        qc.cx(i, i - 1)  # キャリーを伝播\n\n    qc.x(0)  # 最上位ビットを反転\n\n    for i in range(1, n):\n        qc.cx(i, i - 1)  # キャリーを戻す\n\n    for i in range(n):\n        qc.x(i)  # ビットを再び反転して元に戻す\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A34B0337B7B62", "submission_order": 1, "result": "AC", "execution_time": "2055 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for idx in range(n):\n        if idx == 0:\n            qc.x(idx)\n        else:\n            qc.mcx(list(range(idx)), idx)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A358B7AD513E6", "submission_order": 1, "result": "RE", "execution_time": "1633 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx(range(i), i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A358B7AD513E6", "submission_order": 2, "result": "AC", "execution_time": "2797 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx(list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A36794C69C106", "submission_order": 1, "result": "WA", "execution_time": "1565 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n    \n    qc.x(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A36794C69C106", "submission_order": 2, "result": "AC", "execution_time": "1926 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A3C35E36ABCFE", "submission_order": 1, "result": "WA", "execution_time": "1765 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(n-1):\n        qc.append(MCXGate(i+1), list(range(n-1, n-i-3, -1)))\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A3C35E36ABCFE", "submission_order": 2, "result": "AC", "execution_time": "2327 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    for i in range(n-1):\n        qc.append(MCXGate(i+1), list(range(i+2)))\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A41B90FEDF57D", "submission_order": 1, "result": "WA", "execution_time": "1936 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tcarry = QuantumRegister(1)\n\textra = QuantumRegister(n)\n\tqc.add_bits(carry)\n\tqc.add_bits(extra)\n\n\tc = carry[0]\n\tqc.x(c)\n\tfor i in range(n):\n\t\te = extra[i]\n\t\tqc.x(i)\n\t\tqc.ccx(i, c, e)\n\t\tqc.x(i)\n\t\tqc.cx(c, i)\n\t\tqc.swap(c, e)\n\treturn qc\n'''"}
{"problem": "QPC004_A5", "user": "A41B90FEDF57D", "submission_order": 2, "result": "AC", "execution_time": "2443 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\n\tqc.x(0)\n\tfor i in range(1, n):\n\t\tqc.mcx(list(range(i)), i)\n\treturn qc\n'''"}
{"problem": "QPC004_A5", "user": "A43670BAA4640", "submission_order": 1, "result": "WA", "execution_time": "1837 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(n-1)\n    qc.cx(n-1,n-2)\n\n    for i in range(n-3,-1,-1):\n        qc.ccx(i+2,i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A43670BAA4640", "submission_order": 2, "result": "WA", "execution_time": "1752 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(n-1)\n    qc.cx(n-1,n-2)\n\n    for i in range(n-3,-1,-1):\n        qc.ccx(i+2,i+1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A43670BAA4640", "submission_order": 3, "result": "RE", "execution_time": "1736 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(n-1)\n\n    for i in range(n-2,-1,-1):\n        qc.mcx(range(i+1,n),i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A43670BAA4640", "submission_order": 4, "result": "AC", "execution_time": "2140 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    controls = [0]\n\n    for i in range(1,n):\n        qc.mcx(controls, i)\n        controls.append(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A44DA16D354EC", "submission_order": 1, "result": "WA", "execution_time": "1682 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.mcx(list(range(n-1)), n-1)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A44DA16D354EC", "submission_order": 2, "result": "WA", "execution_time": "1597 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    qc.mcx(list(range(n-1)), n-1)\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A453C2CE69ACF", "submission_order": 1, "result": "AC", "execution_time": "1989 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A456ACD9D2AC4", "submission_order": 1, "result": "WA", "execution_time": "1769 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Using the inverse of the increment operation\n    # To decrement by 1, we apply a series of CNOT and X gates\n\n    # Step 1: Apply X to all qubits to flip the representation of (x-1)\n    qc.x(n - 1)\n\n    # Step 2: Construct the decrement using a ripple-carry method\n    for i in range(n - 1):\n        qc.cx(i, i + 1)  # Carry propagation\n    \n    # Step 3: Flip the LSB to complete subtraction\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A456ACD9D2AC4", "submission_order": 2, "result": "WA", "execution_time": "1718 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    # Apply X to all qubits to flip the representation for modular subtraction\n    qc.x(n - 1)\n\n    # Ripple borrow propagation for decrementing\n    for i in range(n - 1):\n        qc.cx(i, i + 1)\n\n    # Final step to complete subtraction by flipping the LSB\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A456ACD9D2AC4", "submission_order": 3, "result": "WA", "execution_time": "1917 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply X gates to all qubits\n    for i in range(n):\n        qc.x(i)\n    \n    # Apply controlled-NOT gates in decreasing order\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n    \n    # Apply X gates to all qubits again\n    for i in range(n):\n        qc.x(i)\n        \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A456ACD9D2AC4", "submission_order": 4, "result": "WA", "execution_time": "1782 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply inverse of the +1 operation\n    # This effectively implements the -1 operation\n    for i in range(n-1, -1, -1):\n        qc.x(i)\n        for j in range(i+1, n):\n            qc.cx(i, j)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A456ACD9D2AC4", "submission_order": 5, "result": "WA", "execution_time": "1827 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # First apply X gates to all qubits\n    for i in range(n):\n        qc.x(i)\n    \n    # Then apply CNOT gates in the correct order\n    for i in range(n-1):\n        qc.cx(i, i+1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A49F3829B053F", "submission_order": 1, "result": "AC", "execution_time": "2346 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(1, n):\n        qc.mcx(list(range(_)), _)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A58A3D91B08E0", "submission_order": 1, "result": "RE", "execution_time": "1719 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # 量子ビットをすべてXゲートで反転させます (NOTゲート)\n    # これは、|x> から |~x> (ビット反転) へのマッピングを作成します。\n    # |x> が 0 の場合、|1> になります。|x> が 2^n - 1 の場合、|0> になります。\n    for i in range(n):\n        qc.x(i)\n\n    # nビットの加算器を実装することで、(x-1) mod 2^n を実現します。\n    # これを行うには、量子フーリエ変換 (QFT) を使用して加算器を構築します。\n    # まず、QFTの逆変換を適用します。\n    # QFTの逆変換は、量子ビットの重ね合わせ状態を周波数領域に変換します。\n    # この変換は、加算操作を位相シフトとして実行できるようにするために必要です。\n    def qft_dagger(circuit, num_qubits):\n        \"\"\"n量子ビットのQFTの逆変換を適用します。\"\"\"\n        for j in range(num_qubits // 2):\n            circuit.swap(j, num_qubits - 1 - j)\n        for j in range(num_qubits):\n            for m in range(j):\n                circuit.cp(-2 * qc.pi / (2**(j - m + 1)), m, j)\n            circuit.h(j)\n\n    # QFTを適用します。\n    # QFTは、量子ビットの重ね合わせ状態を周波数領域に変換します。\n    # これにより、加算操作を位相シフトとして実行できます。\n    def qft(circuit, num_qubits):\n        \"\"\"n量子ビットのQFTを適用します。\"\"\"\n        for j in range(num_qubits - 1, -1, -1):\n            circuit.h(j)\n            for m in range(j):\n                circuit.cp(2 * qc.pi / (2**(j - m + 1)), m, j)\n        for j in range(num_qubits // 2):\n            circuit.swap(j, num_qubits - 1 - j)\n    \n    # QFTを適用します。\n    qft(qc, n)\n\n    # -1 を加算することに相当する位相シフトを適用します。\n    # QFTの性質上、数値の加算は周波数領域での位相シフトに変換されます。\n    # ここでは、各量子ビットに適切な位相シフトを適用して、-1 を加算する効果を実現します。\n    for i in range(n):\n        qc.p(-2 * qc.pi / (2**(n - i)), i)\n\n    # QFTの逆変換を適用して、結果を元の基底に戻します。\n    qft_dagger(qc, n)\n\n    # 再びXゲートを適用して、元の状態に戻します。\n    # これは、最初に適用したXゲートの効果を元に戻し、\n    # 最終的な結果が (x-1) mod 2^n になるようにします。\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 1, "result": "RE", "execution_time": "1841 ms", "memory": "158 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qft_n =qft(n)\n    \n    qc.compose(qft_n,qc,inplace=True)\n    \n    for i in range(n):\n        theta = 2 * pi * 1 * 2**i / 2**n\n        qc.p(theta, i)\n    \n    qc.compose(qft_n.inverse(),qc,inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 2, "result": "RE", "execution_time": "1583 ms", "memory": "158 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qft_n =qft(n)\n    \n    qc.compose(qft_n,qc,inplace=True)\n    \n    for i in range(n):\n        theta = 2 * pi * 1 * 2**i / 2**n\n        qc.p(theta, i)\n    \n    qc.compose(qft_n.inverse(),qc,inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 3, "result": "RE", "execution_time": "1604 ms", "memory": "158 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qft_n =qft(n)\n    \n    qc.compose(qft_n,qc,inplace=True)\n    \n    for i in range(n):\n        theta = 2 * pi * 1 * 2**i / 2**n\n        qc.p(theta, i)\n    \n    qc.compose(qft_n.inverse(),qc,inplace=True)\n    return qc.inverse()\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 4, "result": "DLE", "execution_time": "1696 ms", "memory": "158 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qq=QuantumRegister(n)\n    qc = QuantumCircuit(qq)\n    # Write your code here:\n    qft_n =qft(n)\n    \n    qc.compose(qft_n,qq,inplace=True)\n    \n    for i in range(n):\n        theta = 2 * pi * 1 * 2**i / 2**n\n        qc.p(theta, i)\n    \n    qc.compose(qft_n.inverse(),qq,inplace=True)\n    return qc.inverse()\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 5, "result": "RE", "execution_time": "1791 ms", "memory": "159 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    qq=QuantumRegister(n)\n    for i in range(n):\n        qc.x(i)\n        for j in range(i+1, n):\n            qc.mcx(list(range(i, j)), j)  \n        qc.x(i)\n    return qc.inverse()\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 6, "result": "WA", "execution_time": "1732 ms", "memory": "160 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n        for j in range(i+1, n):\n            qc.mcx(list(range(i, j)), j)  \n        qc.x(i)\n    return qc.inverse()\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 7, "result": "WA", "execution_time": "1895 ms", "memory": "162 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i,i+1)\n    return qc.inverse()\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 8, "result": "RE", "execution_time": "1611 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        #qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        #qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 9, "result": "WA", "execution_time": "1631 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        #qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        #qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 10, "result": "WA", "execution_time": "1723 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1,0,-1):\n        qc.cx(i,i-1)\n        #qc.cx(i-1,i)\n        #qc.cx(i,i-1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 11, "result": "RE", "execution_time": "1645 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n,0,-1):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 12, "result": "WA", "execution_time": "1655 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n-1,0,-1):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 13, "result": "RE", "execution_time": "1644 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n-1,-1,-1):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A5C15FF4AA64E", "submission_order": 14, "result": "AC", "execution_time": "2979 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n-1,0,-1):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n \n    return qc.inverse()\n'''"}
{"problem": "QPC004_A5", "user": "A664F47B7CB57", "submission_order": 1, "result": "WA", "execution_time": "1621 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n          \t\n    for i in range(n):\n    \tprint(i)\n    \tif i == 0:\n    \t\tqc.x(0)\n    \telse:\n    \t\tqc.cx(i,list(range(0,i)))\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A664F47B7CB57", "submission_order": 2, "result": "WA", "execution_time": "1908 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n          \t\n    for i in range(n)[::-1]:\n    \tprint(i)\n    \tif i == 0:\n    \t\tqc.x(0)\n    \telse:\n    \t\tqc.mcx(list(range(0,i)),i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A664F47B7CB57", "submission_order": 3, "result": "AC", "execution_time": "2168 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n          \t\n    for i in range(n):\n    \tprint(i)\n    \tif i == 0:\n    \t\tqc.x(0)\n    \telse:\n    \t\tqc.mcx(list(range(0,i)),i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 1, "result": "WA", "execution_time": "1601 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n\n    qc.x\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 2, "result": "WA", "execution_time": "1798 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(n-1)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 3, "result": "WA", "execution_time": "1615 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(n-1)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 4, "result": "WA", "execution_time": "1891 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 5, "result": "WA", "execution_time": "2812 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 6, "result": "WA", "execution_time": "1983 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-2, -1, -1):\n        qc.cx(i, i+1)\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 7, "result": "WA", "execution_time": "1685 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(0)\n\n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 8, "result": "WA", "execution_time": "1758 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(0)\n\n    for i in range(n-1, 0, -1):\n        qc.cx(i-1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6B7E492906C9", "submission_order": 9, "result": "WA", "execution_time": "2014 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(0)\n\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6DDCE869E67B", "submission_order": 1, "result": "WA", "execution_time": "2093 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    for i in reversed(range(n-1)):\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6DDCE869E67B", "submission_order": 2, "result": "WA", "execution_time": "2640 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A6DDCE869E67B", "submission_order": 3, "result": "AC", "execution_time": "2148 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    controls = []\n    qc.x(0)\n    for i in range(n-1):\n        controls.append(i)\n        mcx = MCXGate(len(controls))\n        qc.append(mcx, controls + [i+1])\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A7D96FE89A7BE", "submission_order": 1, "result": "RE", "execution_time": "1749 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(1,n)):\n        qc.mcx(list(range(1,i)),i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A7D96FE89A7BE", "submission_order": 2, "result": "AC", "execution_time": "2192 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx(list(range(i)),i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A7EC6397830E1", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\nfrom qiskit.circuit.library import QFT\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(QFT(n), range(n))\n    for i in range(n):\n        qc.p(-2*np.pi/2**(i+1), i)\n    qc.append(QFT(n).inverse(), range(n))\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A80834888A106", "submission_order": 1, "result": "WA", "execution_time": "1902 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    for q in range(0, n-1):\n        qc.cx(q, q+1)\n\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A80834888A106", "submission_order": 2, "result": "RE", "execution_time": "1958 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    for q in range(q-1, 0, -1):\n        qc.cx(q, q-1)\n\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A80834888A106", "submission_order": 3, "result": "WA", "execution_time": "2258 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n\n    for q in range(n-1, 0, -1):\n        qc.cx(q, q-1)\n\n    qc.x(n-1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A80834888A106", "submission_order": 4, "result": "WA", "execution_time": "1880 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(n-1)\n    # for q in range(n-1, 0, -1):\n    #     qc.cx(q, q-1)\n\n    for q in range(0, n-1):\n        qc.cx(q+1, q)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A80834888A106", "submission_order": 5, "result": "WA", "execution_time": "1831 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n    # for q in range(n-1, 0, -1):\n    #     qc.cx(q, q-1)\n\n    for q in range(0, n-1):\n        qc.cx(q+1, q)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A80834888A106", "submission_order": 6, "result": "RE", "execution_time": "1853 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(1, n):\n        qc.mcx(list[range(i)], i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A80834888A106", "submission_order": 7, "result": "AC", "execution_time": "2267 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(0)\n\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A80D614691F81", "submission_order": 1, "result": "AC", "execution_time": "2118 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.append(XGate().control(i),qargs=range(i+1))\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A83B6F203D636", "submission_order": 1, "result": "WA", "execution_time": "1849 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.x(i)\n    \n    for i in range(n-1, 0, -1):\n        qc.cx(i, i-1)\n        qc.x(i-1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A83B6F203D636", "submission_order": 2, "result": "WA", "execution_time": "1985 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.x((n-1)-i)\n    \n    for i in range(n-1, 0, -1):\n        qc.cx((n-1)-i, (n-1)-(i-1))\n        qc.x((n-1)-(i-1))\n\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A83B6F203D636", "submission_order": 3, "result": "WA", "execution_time": "1841 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1, -1, -1):\n        qc.x(i)\n        \n        if i > 0:\n            qc.cx(i, i-1)\n\n    \n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A83B6F203D636", "submission_order": 4, "result": "RE", "execution_time": "1738 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n-1, -1, -1):\n        qc.cx(i, i)\n        \n        if i > 0:\n            qc.cx(i, i-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 1, "result": "RE", "execution_time": "1746 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n-1)\n    qc.cx(n-1, n-2)\n\n    for i in range(n-2):\n        x = QuantumRegister(1)\n        qc.add_bits(x)\n        qc.ccx(n - 2 - i, n - 1 +  i,  n - 3- i)\n        if i < n - 3:\n            qc.ccx(n - 2 - i, n- 1 + i, n + i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 2, "result": "RE", "execution_time": "1815 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(n-1)\n    qc.cx(n-1, n-2)\n\n    for i in range(n-2):\n        if i < n - 3:\n            x = QuantumRegister(1)\n            qc.add_bits(x)\n        qc.ccx(n - 2 - i, n - 1 +  i,  n - 3- i)\n        if i < n - 3:\n            qc.ccx(n - 2 - i, n- 1 + i, n + i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import ClassicalRegister, QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qr = QuantumRegister(n)\n    cr = ClassicalRegister(1)\n    qc = QuantumCircuit(qr, cr)\n    # Write your code here:\n    qc.x(n-1)\n\n    for i in range(n):\n        qc.cx(n-1 - i, n-2 - i)\n        qc.measure(qr[n - 2 - i], cr[0])\n\n        with qc.if_test((cr[0], 0)) as else_:\n            break\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import ClassicalRegister, QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=2\n    qc = QuantumCircuit()\n    # Write your code here:\n    qc.x(n-1)\n    qc.cx(n-1, n - 2)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 5, "result": "RE", "execution_time": "1686 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=2\n    qc = QuantumCircuit()\n    # Write your code here:\n    qc.x(n-1)\n    qc.cx(n-1, n - 2)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 6, "result": "WA", "execution_time": "1673 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=2\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.cx(n-1, n - 2)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 7, "result": "WA", "execution_time": "1833 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=3\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.cx(n-1, n - 2)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 8, "result": "WA", "execution_time": "1838 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=5\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.cx(n-1, n - 2)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 9, "result": "WA", "execution_time": "1752 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=5\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.cx(n-1, n - 2)\n\n    for i in range(n-2):\n        if i < n - 3:\n            x = QuantumRegister(1)\n            qc.add_bits(x)\n        qc.ccx(n - 2 - i, n - 1 +  i,  n - 3- i)\n        if i < n - 3:\n            qc.ccx(n - 2 - i, n- 1 + i, n + i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 10, "result": "WA", "execution_time": "1757 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=6\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.cx(n-1, n - 2)\n\n    for i in range(n-2):\n        if i < n - 3:\n            x = QuantumRegister(1)\n            qc.add_bits(x)\n        qc.ccx(n - 2 - i, n - 1 +  i,  n - 3- i)\n        if i < n - 3:\n            qc.ccx(n - 2 - i, n- 1 + i, n + i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 11, "result": "WA", "execution_time": "1773 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    qc.cx(n-1, n - 2)\n\n    for i in range(n-2):\n        if i < n - 3:\n            x = QuantumRegister(1)\n            qc.add_bits(x)\n        qc.ccx(n - 2 - i, n - 1 +  i,  n - 3- i)\n        if i < n - 3:\n            qc.ccx(n - 2 - i, n- 1 + i, n + i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A8C2819D88C38", "submission_order": 12, "result": "RE", "execution_time": "1797 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.ccx(0, 1, 2)\n\n\n    x = QuantumRegister(1)\n    qc.add_bits(x)\n\n    for i in range(n-2):\n        if i == 0:\n            qc.ccx(0, 1, 10)\n        else:\n            x = QuantumRegister(1)\n            qc.add_bits(x)\n            qc.ccx(i + 1, n + i -1,  n + i)\n\n        qc.ccx(n + i, i + 2, i + 3)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A90BD23098F1D", "submission_order": 1, "result": "RE", "execution_time": "1659 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if i == 0:\n            qc.x(qreg[i]) \n        else:\n            qc.cx(qreg[i-1], qreg[i])\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates.mcx import MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 0, -1):\n        qc.append(MCXGate(num_ctrl_qubits=i, ctrl_state=\"0\" * i),\n                  qargs=list(range(i)) + [i])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 2, "result": "RE", "execution_time": "1773 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 0, -1):\n    \n        for j in range(i):\n            qc.x(j)\n    \n        qc.h(i)\n    \n        qc.append(MCPhaseGate(pi, num_qubits=i+1), qargs=list(range(i+1)))\n        qc.h(i)\n    \n        for j in range(i):\n            qc.x(j)\n    \n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 3, "result": "DLE", "execution_time": "1767 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1, 0, -1):\n        for j in range(i):\n            qc.x(j)\n\n        qc.h(i)\n        qc.append(MCPhaseGate(pi, num_ctrl_qubits=i), qargs=list(range(i+1)))\n        qc.h(i)\n\n        for j in range(i):\n            qc.x(j)\n\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 4, "result": "WA", "execution_time": "1777 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, n):\n        for j in range(i):\n            qc.x(j)\n    \n        qc.h(i)\n        qc.append(MCPhaseGate(pi, num_ctrl_qubits=i), qargs=list(range(i)) + [i])\n        qc.h(i)\n        for j in range(i):\n            qc.x(j)\n    \n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 5, "result": "RE", "execution_time": "1671 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import XGate, CXGate, CCXGate\nimport math\n\n\ndef add_one_in_log_depth(qc: QuantumCircuit, data: QuantumRegister, carry: QuantumRegister):\n    n = len(data)\n    \n    for i in range(n):\n        qc.cx(carry[i], data[i])\n\n    for i in range(n):\n        qc.ccx(data[i], carry[i], carry[i+1])\n\n    log_n = math.ceil(math.log2(n))\n\n    block_size = 1\n    while block_size < n:\n        for start in range(0, n, 2*block_size):\n            mid = start + block_size\n            if mid < n:\n                qc.ccx(carry[start], data[mid], carry[mid])\n                qc.cx(carry[start], data[mid])\n                qc.ccx(carry[start], data[mid], carry[mid])\n        block_size *= 2\n\n    for i in range(n):\n        qc.cx(carry[i], data[i])\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(data)\n\n    data = QuantumRegister(n, \"data\")\n    carry = QuantumRegister(n+1, \"carry\")\n    qc.add_register(carry)\n\n    # Step 0: carry[0]を1に初期化 (Xゲート), 他は0のまま\n    qc.x(carry[0])  # carry[0] = 1\n\n    # Step 1: 全ビットを反転 (深さ1扱い: n個のXは並列実行可能)\n    for i in range(n):\n        qc.x(data[i])\n\n    # Step 2: +1 (mod 2^n) の回路を挿入（深さ O(log n)）\n    add_one_in_log_depth(qc, data, carry)\n\n    # Step 3: 再度全ビットを反転 (深さ1)\n    for i in range(n):\n        qc.x(data[i])\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 6, "result": "WA", "execution_time": "1958 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import XGate, CXGate, CCXGate\nimport math\n\n\ndef add_one_in_log_depth(qc: QuantumCircuit, data: QuantumRegister, carry: QuantumRegister):\n    n = len(data)\n    \n    for i in range(n):\n        qc.cx(carry[i], data[i])\n\n    for i in range(n):\n        qc.ccx(data[i], carry[i], carry[i+1])\n\n    log_n = math.ceil(math.log2(n))\n\n    block_size = 1\n    while block_size < n:\n        for start in range(0, n, 2*block_size):\n            mid = start + block_size\n            if mid < n:\n                qc.ccx(carry[start], data[mid], carry[mid])\n                qc.cx(carry[start], data[mid])\n                qc.ccx(carry[start], data[mid], carry[mid])\n        block_size *= 2\n\n    for i in range(n):\n        qc.cx(carry[i], data[i])\n\ndef solve(n: int) -> QuantumCircuit:\n    data = QuantumRegister(n, \"data\")\n    qc = QuantumCircuit(data)\n\n    carry = QuantumRegister(n+1, \"carry\")\n    qc.add_register(carry)\n\n    # Step 0: carry[0]を1に初期化 (Xゲート), 他は0のまま\n    qc.x(carry[0])  # carry[0] = 1\n\n    # Step 1: 全ビットを反転 (深さ1扱い: n個のXは並列実行可能)\n    for i in range(n):\n        qc.x(data[i])\n\n    # Step 2: +1 (mod 2^n) の回路を挿入（深さ O(log n)）\n    add_one_in_log_depth(qc, data, carry)\n\n    # Step 3: 再度全ビットを反転 (深さ1)\n    for i in range(n):\n        qc.x(data[i])\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 7, "result": "DLE", "execution_time": "1518 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import MCPhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(0)\n    for i in range(1, n):\n        qc.h(i)\n        qc.append(MCPhaseGate(math.pi, num_ctrl_qubits=i), list(range(i)) + [i])\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 8, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qft = QFT(n, do_swaps=False, approximation_degree=0)\n\n    qc.append(qft, list(range(n)))\n    \n    for j in range(n):\n        qc.rz(-2*math.pi/2**(j+1), j)\n    \n    qc.append(qft.inverse(), list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A91955BE358B1", "submission_order": 9, "result": "UGE", "execution_time": "1576 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef parallel_qft(n: int) -> QuantumCircuit:\n\n    qc = QuantumCircuit(n)\n    \n    def _qft_recursive(qubits):\n        m = len(qubits)\n        if m == 1:\n            qc.h(qubits[0])\n        else:\n            # qubit 列をおおよそ半分に分割\n            mid = m // 2\n            left = qubits[:mid]\n            right = qubits[mid:]\n            # 両ブロック上で並列に QFT を実施\n            _qft_recursive(left)\n            _qft_recursive(right)\n\n            for i, qi in enumerate(left):\n                for j, qj in enumerate(right):\n                    angle = 2 * math.pi / (2 ** (i + j + 2))\n                    qc.cp(angle, qj, qi)\n                    \n    _qft_recursive(list(range(n)))\n    return qc\n\ndef parallel_iqft(n: int) -> QuantumCircuit:\n    return parallel_qft(n).inverse()\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qft_gate = parallel_qft(n).to_gate(label=\"parallel_QFT\")\n    qc.append(qft_gate, list(range(n)))\n    \n    for j in range(n):\n        qc.rz(-2 * math.pi / (2 ** (j + 1)), j)\n    \n    iqft_gate = parallel_iqft(n).to_gate(label=\"parallel_iQFT\")\n    qc.append(iqft_gate, list(range(n)))\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A92B0ECA33F0A", "submission_order": 1, "result": "AC", "execution_time": "2404 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n        \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A9DF07CD84772", "submission_order": 1, "result": "WA", "execution_time": "1883 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(1,n):\n        qc.x(i)\n\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A9DF07CD84772", "submission_order": 2, "result": "WA", "execution_time": "1744 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.x(i)\n\n    qc.x(0)\n    \n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A9DF07CD84772", "submission_order": 3, "result": "RE", "execution_time": "1816 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.mcx(list(range(i)), i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A9DF07CD84772", "submission_order": 4, "result": "RE", "execution_time": "1748 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    \n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n-1):\n        qc.cx(i, i+1)          \n        qc.ccx(i, i+1, i)     \n    \n    qc.x(n-1)\n    \n    for i in reversed(range(n-1)):\n        qc.ccx(i, i+1, i)\n        qc.cx(i, i+1)\n\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A9DF07CD84772", "submission_order": 5, "result": "RE", "execution_time": "1735 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    \n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n-1):\n        qc.cx(i, i+1)          \n        qc.ccx(i, i+1, i)     \n    \n    qc.x(n-1)\n    \n    for i in reversed(range(n-1)):\n        qc.ccx(i, i+1, i)\n        qc.cx(i, i+1)\n\n\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "A9DF07CD84772", "submission_order": 6, "result": "AC", "execution_time": "2144 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    qc.x(0)\n \n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AA45A9B1FE2C3", "submission_order": 1, "result": "RE", "execution_time": "1528 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n):\n        qc.mcx(list(range(n-i-1)), n-i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AA45A9B1FE2C3", "submission_order": 2, "result": "AC", "execution_time": "1786 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AA94635DE7603", "submission_order": 1, "result": "AC", "execution_time": "2127 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(0)\n    for i in range(1, n):\n        print(i)\n        qc.mcx(list(range(i)),target_qubit=i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AAE6FDC1E8935", "submission_order": 1, "result": "AC", "execution_time": "2210 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(0)\n    for i in range(1, n):\n        qc.mcx(list(range(0, i)), i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ABD8CAB427F4C", "submission_order": 1, "result": "WA", "execution_time": "1950 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, (i + 1)%n)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ABD8CAB427F4C", "submission_order": 2, "result": "WA", "execution_time": "2113 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n      qc.swap(i, i+1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ABD8CAB427F4C", "submission_order": 3, "result": "WA", "execution_time": "1645 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(n-1)):\n      qc.swap(i, i+1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC0A00B40C51A", "submission_order": 1, "result": "RE", "execution_time": "1711 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(9)\n    for i in range(n - 1):\n        qc.mcx(list(range(n - 1 - i, n)), n - i - 2)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC0A00B40C51A", "submission_order": 2, "result": "WA", "execution_time": "1692 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n - 1)\n    for i in range(n - 1):\n        qc.mcx(list(range(n - 1 - i, n)), n - i - 2)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC0A00B40C51A", "submission_order": 3, "result": "AC", "execution_time": "1918 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n - 1):\n        qc.mcx(list(range(0, i + 1)), i + 1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC4DFA0159494", "submission_order": 1, "result": "WA", "execution_time": "1975 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)  \n        if i < n - 1:\n            qc.cx(i, i + 1)  \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC4DFA0159494", "submission_order": 2, "result": "WA", "execution_time": "1744 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)  \n    \n    for i in range(n - 1):  \n        qc.cx(i, i + 1)  \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC4DFA0159494", "submission_order": 3, "result": "WA", "execution_time": "1606 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    \n    for i in range(1, n):\n        for j in range(i):\n            qc.x(j)\n        \n        if i == 1:\n            qc.cx(0, 1)\n        elif i == 2:\n            qc.ccx(0, 1, 2)\n        else:\n            qc.mcx(list(range(i)), i)\n        \n        for j in range(i):\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC4DFA0159494", "submission_order": 4, "result": "DLE", "execution_time": "1366 ms", "memory": "141 MiB", "code": "'''python\n# from qiskit import QuantumCircuit\n\n# def solve(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n    \n#     qc.x(0)\n    \n#     for i in range(1, n):\n#         for j in range(i):\n#             qc.x(j)\n        \n#         if i == 1:\n#             qc.cx(0, 1)\n#         elif i == 2:\n#             qc.ccx(0, 1, 2)\n#         else:\n#             qc.mcx(list(range(i)), i)\n        \n#         for j in range(i):\n#             qc.x(j)\n    \n#     return qc\n\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # +1演算の実装\n    plus_one_qc = QuantumCircuit(n)\n    plus_one_qc.x(0)\n    \n    for i in range(1, n):\n        for j in range(i):\n            plus_one_qc.x(j)\n        \n        if i == 1:\n            plus_one_qc.cx(0, 1)\n        elif i == 2:\n            plus_one_qc.ccx(0, 1, 2)\n        else:\n            plus_one_qc.mcx(list(range(i)), i)\n        \n        for j in range(i):\n            plus_one_qc.x(j)\n    \n    # +1演算の逆演算（-1演算）を実行\n    qc = qc.compose(plus_one_qc.inverse())\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC4DFA0159494", "submission_order": 5, "result": "WA", "execution_time": "1822 ms", "memory": "142 MiB", "code": "'''python\n# from qiskit import QuantumCircuit\n\n# def solve(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n    \n#     qc.x(0)\n    \n#     for i in range(1, n):\n#         for j in range(i):\n#             qc.x(j)\n        \n#         if i == 1:\n#             qc.cx(0, 1)\n#         elif i == 2:\n#             qc.ccx(0, 1, 2)\n#         else:\n#             qc.mcx(list(range(i)), i)\n        \n#         for j in range(i):\n#             qc.x(j)\n    \n#     return qc\n\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    \n    for i in range(1, n):\n        if i == 1:\n            qc.cx(0, 1)\n        else:\n            qc.cx(i-1, i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC642BF2CE1C7", "submission_order": 1, "result": "AC", "execution_time": "1941 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC858E47183D1", "submission_order": 1, "result": "WA", "execution_time": "1822 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC858E47183D1", "submission_order": 2, "result": "WA", "execution_time": "1715 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    for i in range(n - 1):\n        qc.cx(0, i + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AC858E47183D1", "submission_order": 3, "result": "WA", "execution_time": "1591 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(0)\n    for i in range(n - 2):\n        qc.cx(0, i + 1)\n    qc.cx(n - 2, n - 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD0D2BD93B5D5", "submission_order": 1, "result": "AC", "execution_time": "2781 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n)):\n        if i == 0:\n            qc.x(i)\n        else:\n            qc.append(XGate().control(i), range(i + 1))\n    return qc.inverse()\n\n# if __name__ == \"__main__\":\n#     from qiskit.quantum_info import Statevector\n#     import numpy as np\n\n#     qc = solve(3)\n#     print(qc)\n#     sv = Statevector.from_label('001')\n#     print(sv.evolve(qc))\n'''"}
{"problem": "QPC004_A5", "user": "AD267B9568D02", "submission_order": 1, "result": "RE", "execution_time": "1694 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(1,n):\n        qc.mcp(list(range(i)),i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD267B9568D02", "submission_order": 2, "result": "RE", "execution_time": "1711 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(1,n):\n        qc.mcp(list(range(i)),i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD267B9568D02", "submission_order": 3, "result": "RE", "execution_time": "1483 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(1,n):\n        qc.mcx(list(range(i)),i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD267B9568D02", "submission_order": 4, "result": "RE", "execution_time": "1602 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(1,n):\n        qc.mcx(list(range(i)),i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD267B9568D02", "submission_order": 5, "result": "AC", "execution_time": "2079 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for _ in range(1,n):\n        qc.mcx(list(range(_)),_)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD31F2D226DAD", "submission_order": 1, "result": "WA", "execution_time": "1805 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD31F2D226DAD", "submission_order": 2, "result": "WA", "execution_time": "1658 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-1)\n    for i in range(n-1):\n        qc.cx(n-i-1, n-i-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD31F2D226DAD", "submission_order": 3, "result": "WA", "execution_time": "1787 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AD31F2D226DAD", "submission_order": 4, "result": "AC", "execution_time": "1980 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        p=[j for j in range(i+1)]\n        qc.mcx(p, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADB9D770A6D21", "submission_order": 1, "result": "WA", "execution_time": "1940 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n\n    for i in range(n - 1):\n        qc.cx(i, i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADB9D770A6D21", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n - 3):\n        qc.cx(i, i+1)\n        qc.x(i)\n        qc.x(i+1)\nqc.cx(n-2 n-1)\nqc.x(n-2)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADB9D770A6D21", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\nqc.x(n-2)\nqc.cx(n-2 n-1)\n    for i in range(n - 3,0,-1):\n        qc.x(i)\n        qc.x(i+1)\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADB9D770A6D21", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-2)\n    qc.cx(n-2 n-1)\n    for i in range(n - 3,0,-1):\n        qc.x(i)\n        qc.x(i+1)\n        qc.cx(i, i+1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADB9D770A6D21", "submission_order": 5, "result": "WA", "execution_time": "1841 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-2)\n    qc.cx(n-2,n-1)\n\n    for i in range(n - 3,0,-1):\n        qc.x(i)\n        qc.x(i+1)\n        qc.cx(i, i+1)\n        \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADB9D770A6D21", "submission_order": 6, "result": "WA", "execution_time": "1825 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-2)\n    qc.cx(n-2,n-1)\n\n    for i in range(n - 3,0,-1):\n        qc.x(i)\n        qc.x(i+1)\n        qc.cx(i, i+1)\n        \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADB9D770A6D21", "submission_order": 7, "result": "WA", "execution_time": "2036 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n-2)\n    qc.cx(n-2,n-1)\n\n    for i in range(n - 3,0,-1):\n        qc.x(i)\n        qc.x(i+1)\n        qc.cx(i, i+1)\n        \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADE0C805C984A", "submission_order": 1, "result": "WA", "execution_time": "1963 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef inc(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 1, -1):\n        qc.mcx(list(range(i)), i)\n    qc.x(0)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(inc(n).inverse(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "ADE0C805C984A", "submission_order": 2, "result": "AC", "execution_time": "2057 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef inc(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1, 0, -1):\n        qc.mcx(list(range(i)), i)\n    qc.x(0)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(inc(n).inverse(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AE0AE77326A74", "submission_order": 1, "result": "AC", "execution_time": "2094 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n : int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        if(i == 0):\n            qc.x(0)\n        else:\n            qc.mcx(list(range(0,i,1)),i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AE747817413D6", "submission_order": 1, "result": "WA", "execution_time": "1685 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, n):\n        qc.mcx(list(range(i, n)), i - 1)\n    qc.x(n - 1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AE747817413D6", "submission_order": 2, "result": "WA", "execution_time": "1862 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(1, n):\n      qc.mcx(list(range(0, n - i)), n - i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AE747817413D6", "submission_order": 3, "result": "WA", "execution_time": "1713 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(n - 1)\n    for i in reversed(range(1, n)):\n      qc.mcx(list(range(i, n)), i - 1)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AE747817413D6", "submission_order": 4, "result": "AC", "execution_time": "2581 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in reversed(range(1, n)):\n      qc.mcx(list(range(0, n - i)), n - i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AE7C86D20EF8C", "submission_order": 1, "result": "RE", "execution_time": "2007 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0,n): qc.x(i)\n    qc.cx(1, 0)\n    qc.cx(2, 1)\n    qc.ccx(0, 1, 2)\n    qc.cx(3, 2)\n    qc.ccx(1, 2, 3)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AE7C86D20EF8C", "submission_order": 2, "result": "RE", "execution_time": "1549 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0,n): \n        qc.x(i)\n        \n    qc.cx(1, 0)\n    qc.cx(2, 1)\n    qc.ccx(0, 1, 2)\n    qc.cx(3, 2)\n    qc.ccx(1, 2, 3)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AE7C86D20EF8C", "submission_order": 3, "result": "WA", "execution_time": "1765 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(0,n): qc.x(i)\n    for i in range(0, n-3):   \n        qc.cx(i+1, i)\n        qc.cx(i+2, i+1)\n        qc.ccx(i, i+1, i+2)\n        qc.cx(i+3, i+2)\n        qc.ccx(i+1, i+2, i+3)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AEC76BB21C27D", "submission_order": 1, "result": "RE", "execution_time": "1736 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    numbers=[0,1,2,3,4,5,6,7,8,9,10]\n    qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        qc.mcx(numbers[i+1:10],i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AEC76BB21C27D", "submission_order": 2, "result": "WA", "execution_time": "1784 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    numbers=[0,1,2,3,4,5,6,7,8,9,10]\n    qc.x(n-1)\n    for i in range(n-2,-1,-1):\n        qc.mcx(numbers[i+1:n],i)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AEC76BB21C27D", "submission_order": 3, "result": "AC", "execution_time": "2374 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc = QuantumCircuit(n)\n    numbers=[0,1,2,3,4,5,6,7,8,9,10]\n    qc.x(0)\n    for i in range(1, n):\n\n        qc.mcx(numbers[0:i],i)\n\n    return qc\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AECDA9E4592E7", "submission_order": 1, "result": "AC", "execution_time": "1974 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx(list(range(i)),i)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AF5290732D6A9", "submission_order": 1, "result": "WA", "execution_time": "1950 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n-1):\n        qc.cx(i,i+1)\n    for i in range(0, n-1):\n        qc.cx(i,i+1)                  \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AF6861F29903A", "submission_order": 1, "result": "AC", "execution_time": "1988 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(n-1):\n        qc.mcx([j for j in range(i+1)], i+1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AF7625F74658A", "submission_order": 1, "result": "RE", "execution_time": "1622 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.mcx(list(range(1,n-i)), i, ctrl_state='0')\n    qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AF7625F74658A", "submission_order": 2, "result": "WA", "execution_time": "1677 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.mcx(list(range(i+1,n)), i, ctrl_state=0)\n    qc.x(n-1)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AF7625F74658A", "submission_order": 3, "result": "AC", "execution_time": "2854 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n-1):\n        qc.mcx(list(range(n-i-1)), n-i-1, ctrl_state=0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AFD32806568B8", "submission_order": 1, "result": "WA", "execution_time": "1789 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # 加算回路では、量子ビットのビットごとに加算を行うが、これを逆にします。\n    for i in range(n):\n        # CNOT ゲートで、減算操作を行うためにキャリーを伝播\n        qc.cx(i, (i + 1) % n)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AFD32806568B8", "submission_order": 2, "result": "WA", "execution_time": "1814 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.x(qubit) \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AFD32806568B8", "submission_order": 3, "result": "WA", "execution_time": "1769 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.cx(qubit, (qubit + 1) % n)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AFD32806568B8", "submission_order": 4, "result": "WA", "execution_time": "1915 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit) \n    \n    for qubit in range(n):\n        qc.x(qubit)\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AFFE116351788", "submission_order": 1, "result": "WA", "execution_time": "1648 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, (i + 1) % n)\n\n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AFFE116351788", "submission_order": 2, "result": "RE", "execution_time": "1606 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    add_one_circuit = QuantumCircuit(n)\n\n    add_one_circuit.h(range(n))\n\n    for i in range(n):\n        for j in range(i):\n            add_one_circuit.cp(-2 * np.pi / (2 ** (i - j + 1)), j, i)\n    \n\n    add_one_circuit.h(range(n))\n    \n    minus_one_circuit = add_one_circuit.inverse()\n    \n    qc.compose(minus_one_circuit, inplace=True)\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AFFE116351788", "submission_order": 3, "result": "WA", "execution_time": "1706 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n   \n    qc = QuantumCircuit(n)\n    \n  \n    for i in range(n - 1):\n        qc.mcx(control_qubits=list(range(i + 1)), target_qubit=i + 1, mode='noancilla')\n    qc.x(0) \n    qc = qc.inverse()\n\n    return qc\n    \n    return qc\n'''"}
{"problem": "QPC004_A5", "user": "AFFE116351788", "submission_order": 4, "result": "WA", "execution_time": "1788 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n   \n    qc = QuantumCircuit(n)\n    \n    qc.x(range(n))\n    \n    for i in range(n - 1):\n        qc.mcx(control_qubits=list(range(i + 1)), target_qubit=i + 1, mode='noancilla')\n    qc.x(0) \n\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A03298D65B45F", "submission_order": 1, "result": "RE", "execution_time": "1573 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A03298D65B45F", "submission_order": 2, "result": "WA", "execution_time": "1745 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    import math\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A03298D65B45F", "submission_order": 3, "result": "WA", "execution_time": "1787 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = 4 * math.atan(math.sqrt(6)/ (3 + math.sqrt(3)))\n\n    qc.ry(theta, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A03298D65B45F", "submission_order": 4, "result": "WA", "execution_time": "1925 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(1.9106332362490188, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A03298D65B45F", "submission_order": 5, "result": "WA", "execution_time": "1815 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # 1/sqrt(3) の係数を得るための回転\n    theta = 2 * np.arccos(1 / np.sqrt(3))\n    qc.ry(theta, 0)  # q[0] に振幅を調整\n    \n    # q[1] にアダマールを適用し、重ね合わせを作る\n    qc.h(1)\n    \n    # 位相調整\n    qc.cp(-np.pi, 0, 1)  # CPhase(-π)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A03298D65B45F", "submission_order": 6, "result": "AC", "execution_time": "1854 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.ry(1.9106332362490188, 1)\n    qc.ch(1, 0)\n    qc.cx(0, 1)\n    qc.x(1)\n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 1, "result": "RE", "execution_time": "1569 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    c = 1/np.sqrt(3)\n\n    U = np.array([[c, c, c, 0], [c, c, 0, c], [0, c, c, c], [-c, 0, c, c]])\n\n    qc.unitary(U, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 2, "result": "RE", "execution_time": "1560 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    c = 1/np.sqrt(3)\n\n    U = [[c, c, c, 0], [c, c, 0, c], [0, c, c, c], [-c, 0, c, c]]\n\n    qc.unitary(U, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 3, "result": "RE", "execution_time": "1558 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    c = 1/math.sqrt(3)\n\n    U = [[c, c, c, 0], [c, c, 0, c], [0, c, c, c], [-c, 0, c, c]]\n\n    qc.unitary(U, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 4, "result": "RE", "execution_time": "1689 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(2 * np.arccos(1/np.sqrt(3)), 1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cz(1, 0)\n    qc.x(1)\n    \n    # |10⟩ \n    qc.cx(0, 1)\n    qc.ry(2 * np.arccos(1/np.sqrt(3)), 1)\n    qc.cx(0, 1)\n    \n    \n    qc.z(1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 5, "result": "RE", "execution_time": "1939 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(2 * math.arccos(1/np.sqrt(3)), 1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cz(1, 0)\n    qc.x(1)\n    \n    # |10⟩ \n    qc.cx(0, 1)\n    qc.ry(2 * math.arccos(1/np.sqrt(3)), 1)\n    qc.cx(0, 1)\n    \n    #\n    qc.z(1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 6, "result": "RE", "execution_time": "1944 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(2 * math.arccos(1/math.sqrt(3)), 1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cz(1, 0)\n    qc.x(1)\n    \n    # |10⟩ \n    qc.cx(0, 1)\n    qc.ry(2 * mat.arccos(1/math.sqrt(3)), 1)\n    qc.cx(0, 1)\n    \n    #\n    qc.z(1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 7, "result": "RE", "execution_time": "1729 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(2 * math.arccos(1/math.sqrt(3)), 1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cz(1, 0)\n    qc.x(1)\n    \n    # |10⟩ \n    qc.cx(0, 1)\n    qc.ry(2 * math.arccos(1/math.sqrt(3)), 1)\n    qc.cx(0, 1)\n    \n    #\n    qc.z(1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 8, "result": "WA", "execution_time": "2107 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(2 * math.acos(1/math.sqrt(3)), 1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cz(1, 0)\n    qc.x(1)\n    \n    # |10⟩ \n    qc.cx(0, 1)\n    qc.ry(2 * math.acos(1/math.sqrt(3)), 1)\n    qc.cx(0, 1)\n    \n    #\n    qc.z(1)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1434A6184FF8", "submission_order": 9, "result": "WA", "execution_time": "1903 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.h(0)\n    \n    theta = 2 * math.acos(1/math.sqrt(3))\n    qc.cry(theta, 0, 1)\n    \n    qc.cz(0, 1)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 1, "result": "WA", "execution_time": "1764 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    # Create a quantum circuit with 2 qubits\n    qc = QuantumCircuit(2)\n    \n    # First, apply a custom transformation to achieve the desired superpositions\n    # We need specific rotation angles to get the 1/√3 amplitudes\n    \n    # For the first transition (|00⟩ transformation)\n    theta1 = 2 * 0.6154797086703874  # arccos(1/√3)\n    qc.ry(theta1, 0)\n    qc.cx(0, 1)\n    qc.rz(3.141592653589793, 1)  # π rotation for the minus sign\n    qc.cx(0, 1)\n    \n    # For the second transition (|10⟩ transformation)\n    theta2 = 2 * 0.6154797086703874  # same angle as it's also 1/√3\n    qc.x(0)  # Flip first qubit to handle |10⟩ case\n    qc.ry(theta2, 0)\n    qc.cx(0, 1)\n    qc.x(0)  # Restore first qubit\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 2, "result": "WA", "execution_time": "1749 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply CNOT gate with the first qubit as control and the second qubit as target\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\nfrom qiskit.extensions import UnitaryGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Define the transformation matrix\n    U = np.array([\n        [1/np.sqrt(3), 0, 1/np.sqrt(3), 0],\n        [1/np.sqrt(3), 0, 0, 0],\n        [0, 0, 1/np.sqrt(3), 0],\n        [-1/np.sqrt(3), 0, 1/np.sqrt(3), 1]\n    ])\n\n    # Convert to a UnitaryGate\n    gate = UnitaryGate(U)\n    \n    # Apply the unitary gate to the 2-qubit circuit\n    qc.append(gate, [0, 1])\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 4, "result": "WA", "execution_time": "2083 ms", "memory": "162 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Apply a Y rotation on qubit 0 to create superposition\n    qc.ry(2 * np.arccos(1 / np.sqrt(3)), 0)\n\n    # Step 2: Use a CNOT to entangle qubit 0 and qubit 1\n    qc.cx(0, 1)\n\n    # Step 3: Apply phase shifts to introduce negative sign\n    qc.rz(np.pi, 1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 5, "result": "WA", "execution_time": "1884 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    # Initialize a quantum circuit with 2 qubits\n    qc = QuantumCircuit(2)\n    \n    # To achieve the desired transformations:\n    # |00⟩ → (1/√3)(|00⟩ + |01⟩ - |11⟩)\n    # |10⟩ → (1/√3)(|00⟩ + |10⟩ + |11⟩)\n    \n    # First, apply a rotation to create the proper superposition\n    theta = 2 * np.arccos(1/np.sqrt(3))\n    \n    # Apply Ry rotation to first qubit\n    qc.ry(theta, 0)\n    \n    # Apply controlled operations for state preparation\n    qc.cx(0, 1)\n    \n    # Apply phase adjustment\n    qc.rz(np.pi, 1)\n    \n    # Additional transformations for proper superposition\n    qc.h(1)\n    \n    # Apply controlled-Z for phase alignment\n    qc.cz(0, 1)\n    \n    # Final adjustments for amplitude matching\n    qc.ry(-theta/2, 0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 6, "result": "WA", "execution_time": "1923 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply a Hadamard gate to the first qubit to create superposition\n    qc.h(0)\n    \n    # Apply a CNOT gate with the first qubit as control and the second as target\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 7, "result": "WA", "execution_time": "2027 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import U3Gate\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Transform |00⟩ → (|00⟩ + |01⟩ - |11⟩) / sqrt(3)\n    # Apply a rotation gate to the first qubit to create the desired amplitudes\n    theta = 2 * np.arccos(np.sqrt(2 / 3))  # Angle for the correct amplitudes\n    qc.u(theta, np.pi, 0, 0)  # Apply a U3 gate to the first qubit\n    \n    # Step 2: Apply a Hadamard gate to the first qubit to create superposition\n    qc.h(0)\n    \n    # Step 3: Use a CNOT gate to transform |01⟩ to |11⟩\n    qc.cx(0, 1)\n    \n    # Step 4: Adjust phases for the |11⟩ state\n    qc.z(1)  # Apply a Z gate to the second qubit to introduce a phase of -1\n    \n    # Step 5: Transform |10⟩ → (|00⟩ + |10⟩ + |11⟩) / sqrt(3)\n    # Use controlled gates to ensure the transformation only applies when the first qubit is |1⟩\n    qc.cu(theta, 0, 0, 0, 0, 1)  # Controlled-U gate\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 8, "result": "WA", "execution_time": "1907 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Step 1: Transform |00⟩ → (|00⟩ + |01⟩ - |11⟩) / sqrt(3)\n    # Apply a Hadamard gate to the first qubit to create superposition\n    qc.h(0)\n    \n    # Apply a controlled-Z gate to introduce the phase of -1 for |11⟩\n    qc.cz(0, 1)\n    \n    # Step 2: Transform |10⟩ → (|00⟩ + |10⟩ + |11⟩) / sqrt(3)\n    # Apply a controlled-Hadamard gate to the second qubit when the first qubit is |1⟩\n    qc.ch(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 9, "result": "WA", "execution_time": "1903 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import sqrt\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \n    # Apply Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply controlled gates to create the desired state\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A1652591E44F2", "submission_order": 10, "result": "WA", "execution_time": "1971 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Step 1: Create a superposition on the first qubit\n    qc.ry(2 * (1/3)**0.5, 0)  # Custom Ry to match 1/sqrt(3) coefficient\n\n    # Step 2: Use CNOT to entangle second qubit with control on the first\n    qc.cx(0, 1)\n\n    # Step 3: Apply phase shift to adjust the sign of |11⟩\n    qc.z(1)  # Apply Z on the second qubit to introduce the required negative sign\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A221F8F00689E", "submission_order": 1, "result": "WA", "execution_time": "1725 ms", "memory": "160 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    theta = 2 * math.atan(math.sqrt(2))\n \n    qc.rx(theta, 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A221F8F00689E", "submission_order": 2, "result": "WA", "execution_time": "1658 ms", "memory": "160 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    theta = 2 * math.atan(math.sqrt(2))\n \n    qc.rx(theta, 1)\n    qc.z(1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(1, 0)\n \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A36EFFC8BFF0E", "submission_order": 1, "result": "AC", "execution_time": "1777 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    phi = 2 * math.atan(math.sqrt(2))\n    qc.ry(phi, 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A3E96A9642041", "submission_order": 1, "result": "WA", "execution_time": "1793 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A3E96A9642041", "submission_order": 2, "result": "WA", "execution_time": "1874 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.ch(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A3E96A9642041", "submission_order": 3, "result": "WA", "execution_time": "1797 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.ch(0,1)\n    qc.cx(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A3E96A9642041", "submission_order": 4, "result": "WA", "execution_time": "1766 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    qc.ch(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A3E96A9642041", "submission_order": 5, "result": "AC", "execution_time": "1947 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.atan(math.sqrt(2)),1)\n    qc.ch(1,0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A5BB9BB76E263", "submission_order": 1, "result": "RE", "execution_time": "1727 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 2 * math.atan(math.sqrt(2))\n \n    qc.ry(theta, 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A5BB9BB76E263", "submission_order": 2, "result": "AC", "execution_time": "1886 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    theta = 2 * math.atan(math.sqrt(2))\n \n    qc.ry(theta, 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(1, 0)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A5C0137D6907F", "submission_order": 1, "result": "RE", "execution_time": "1798 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    # Apply a Hadamard gate to the first qubit\n    qc.h(0)\n    \n    # Apply a controlled phase rotation to create the necessary superpositions\n    qc.cp(-2 * math.pi / 3, 0, 1)  # Apply a controlled phase shift from qubit 0 to qubit 1\n\n    # Apply a Hadamard gate to the second qubit\n    qc.h(1)\n\n    # Apply a controlled NOT gate to entangle the qubits\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A60CF20373DDB", "submission_order": 1, "result": "WA", "execution_time": "1941 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\tqc.ry(2 * acos(1 / sqrt(3)), 0)\n\tqc.x(1)\n\tqc.ch(0, 1)\n\treturn qc\n'''"}
{"problem": "QPC004_A6", "user": "A60CF20373DDB", "submission_order": 2, "result": "WA", "execution_time": "1742 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\tqc.ry(2 * acos(1 / sqrt(3)), 0)\n\tqc.x(1)\n\tqc.ch(0, 1)\n\tqc.x(1)\n\tqc.cx(1, 0)\n\tqc.x(1)\n\tqc.swap(0, 1)\n\treturn qc\n'''"}
{"problem": "QPC004_A6", "user": "A60CF20373DDB", "submission_order": 3, "result": "AC", "execution_time": "2316 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import sqrt, acos\n\ndef solve() -> QuantumCircuit:\n\tqc = QuantumCircuit(2)\n\tqc.swap(0, 1)\n\tqc.ry(2 * acos(1 / sqrt(3)), 0)\n\tqc.x(1)\n\tqc.ch(0, 1)\n\tqc.x(1)\n\tqc.cx(1, 0)\n\tqc.x(1)\n\treturn qc\n'''"}
{"problem": "QPC004_A6", "user": "A6215EB78ED20", "submission_order": 1, "result": "AC", "execution_time": "1963 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.atan(math.sqrt(2)),1)\n    qc.ch(1,0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A6270302ABB84", "submission_order": 1, "result": "RE", "execution_time": "1687 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n\n    qc.ry(math.asin( sqrt(2)/sqrt(3) )*2, 0)\n    qc.cry(-math.pi/2, 0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A6270302ABB84", "submission_order": 2, "result": "RE", "execution_time": "1707 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.asin( sqrt(2)/sqrt(3) )*2, 0)\n    qc.cry(-math.pi/2, 0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A6270302ABB84", "submission_order": 3, "result": "RE", "execution_time": "1712 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.asin( sqrt(2)/sqrt(3) )*2, 0)\n    qc.ch(0,1)\n\n    qc.x(1)\n    qc.cx(1,0)\n    qc.x(1)\n    \n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A6270302ABB84", "submission_order": 4, "result": "RE", "execution_time": "1719 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.asin( sqrt(2)/sqrt(3) )*2, 1)\n    qc.ch(1,0)\n\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    \n    qc.cz(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A6270302ABB84", "submission_order": 5, "result": "WA", "execution_time": "1988 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.asin( math.sqrt(2)/math.sqrt(3) )*2, 0)\n    qc.ch(0,1)\n\n    qc.x(1)\n    qc.cx(1,0)\n    qc.x(1)\n    \n    qc.cz(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A6270302ABB84", "submission_order": 6, "result": "RE", "execution_time": "1840 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.asin( sqrt(2)/sqrt(3) )*2, 1)\n    qc.ch(1,0)\n\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    \n    qc.cz(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A6270302ABB84", "submission_order": 7, "result": "AC", "execution_time": "1971 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(math.asin( math.sqrt(2)/math.sqrt(3) )*2, 1)\n    qc.ch(1,0)\n\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    \n    qc.cz(0,1)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A65DEFD74A968", "submission_order": 1, "result": "RE", "execution_time": "1733 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n\n    U = np.array([[1/np.sqrt(3), 1/np.sqrt(3), 1, 1],[0, 1/np.sqrt(3), 0, 0],[1/np.sqrt(3), 0, 0, 0],[-1/np.sqrt(3), 1/np.sqrt(3), 0, 0]])\n    qc.unitary(U, [0,1])\n    # theta1 = 2 * math.atan(math.sqrt(2))\n    # theta2 = 2 * math.atan(1)\n    \n    # #00\n    # qc.x(0)\n    # qc.cry(theta1, 0, 1)\n    # qc.cry(theta2, 1, 0)\n    # qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A66A9D6846D55", "submission_order": 1, "result": "RE", "execution_time": "1997 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.u1(sqrt(3)/2, 1)\n    qc.cx(0, 1)\n\n    qc.x(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A66A9D6846D55", "submission_order": 2, "result": "RE", "execution_time": "1580 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    qc.h(0)\n    qc.u1((3)^(1/2)/2, 1)\n    qc.cx(0, 1)\n\n    qc.x(0)\n    qc.h(1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A729C8233D0B5", "submission_order": 1, "result": "WA", "execution_time": "1823 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(0, 1)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A729C8233D0B5", "submission_order": 2, "result": "RE", "execution_time": "1637 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2 * np.arccos(np.sqrt(2/3))\n    qc.cry(theta, 0, 1)\n\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A729C8233D0B5", "submission_order": 3, "result": "WA", "execution_time": "1878 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    theta = 2 * np.arccos(np.sqrt(2/3))\n    qc.cry(theta, 0, 1)\n\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A729C8233D0B5", "submission_order": 4, "result": "WA", "execution_time": "1846 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    \n    \n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cp(-np.pi/2, 0, 1)  # Controlled phase gate\n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A729C8233D0B5", "submission_order": 5, "result": "WA", "execution_time": "2637 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    \n    # Apply controlled gates to create the desired states\n    qc.cx(0, 1)\n    qc.h(1)\n    qc.cp(-np.pi, 0, 1)  # Controlled phase gate for the -|11> term\n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A729C8233D0B5", "submission_order": 6, "result": "WA", "execution_time": "1961 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)\n    \n    qc.cx(0, 1)\n    \n   \n    qc.cp(np.pi, 0, 1)  \n    \n    \n    qc.h(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A77B1B3E99223", "submission_order": 1, "result": "AC", "execution_time": "1883 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\n\ndef solve():\n    l, r = QuantumRegister(1), QuantumRegister(1)\n    qc = QuantumCircuit(l, r)\n\n    qc.ry(math.acos(math.sqrt(1 / 3)) * 2, r)\n    qc.ch(r, l)\n\n    qc.x(r)\n    qc.cx(l, r)\n    qc.cz(l, r)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A9225E7859746", "submission_order": 1, "result": "WA", "execution_time": "1861 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    qc.ry(1.230, 0)\n    qc.rz(-0.785, 0)\n    qc.cx(0, 1)\n    qc.ry(0.628, 0)\n    qc.rz(2.111, 1)\n    qc.cx(0, 1)\n    qc.ry(-1.570, 0)\n    qc.rz(0.349, 0)\n    qc.cx(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 1, "result": "RE", "execution_time": "1910 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 2, "result": "WA", "execution_time": "1841 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 3, "result": "RE", "execution_time": "1742 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(10, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 4, "result": "WA", "execution_time": "2059 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 5, "result": "WA", "execution_time": "2027 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(1/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 6, "result": "WA", "execution_time": "1744 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(1/2)\n    qc.ry(2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt{3})\n    qc.ry(2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 8, "result": "WA", "execution_time": "1722 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 9, "result": "WA", "execution_time": "1826 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(-2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 10, "result": "WA", "execution_time": "2039 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 11, "result": "WA", "execution_time": "1884 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 12, "result": "WA", "execution_time": "1649 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 13, "result": "WA", "execution_time": "1849 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 14, "result": "WA", "execution_time": "2298 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 15, "result": "WA", "execution_time": "1901 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 0)\n    qc.cx(0, 1)\n    qc.ch(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cx(0,1)\n    qc.cx(1,0)\n    qc.cx(0,1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 16, "result": "WA", "execution_time": "1845 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A98E73B4E1DB7", "submission_order": 17, "result": "AC", "execution_time": "1714 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle=np.arcsin(np.sqrt(2)/np.sqrt(3))\n    qc.ry(2*angle, 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "A9A62A6F2C2CD", "submission_order": 1, "result": "RE", "execution_time": "1713 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    # 定義するユニタリ行列 U (計算基底順序: |00>, |01>, |10>, |11>)\n    U = (1/np.sqrt(3)) * np.array([\n        [ 1,  1,  1,  0],\n        [ 1, -1,  0,  1],\n        [ 0, -1,  1, -1],\n        [-1,  0,  1,  1]\n    ], dtype=complex)\n    \n    # 2量子ビット全体に対して U を実装\n    qc.unitary(U, [0, 1], label=\"U\")\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AAB2473C76F2F", "submission_order": 1, "result": "WA", "execution_time": "1951 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AAB2473C76F2F", "submission_order": 2, "result": "WA", "execution_time": "1871 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.ch(0, 1)\n    qc.cx(1, 0)\n    qc.h(1)\n    qc.cx(1, 0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AAB2473C76F2F", "submission_order": 3, "result": "WA", "execution_time": "1837 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cry(2*np.arccos(2/3), 0, 1)\n    qc.cry(2*np.arccos(-1/np.sqrt(10)), 1, 0)\n    qc.ry(2*np.arccos(1/np.sqrt(3)), 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.cz(1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AAB2473C76F2F", "submission_order": 4, "result": "WA", "execution_time": "2003 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cry(np.arccos(2/3), 0, 1)\n    qc.cry(np.arccos(-1/np.sqrt(10)), 1, 0)\n    qc.ry(np.arccos(1/np.sqrt(3)), 1)\n    qc.cx(1, 0)\n    qc.ch(1, 0)\n    qc.cz(1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AAB2473C76F2F", "submission_order": 5, "result": "WA", "execution_time": "1930 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cry(2*np.arccos(2/3), 0, 1)\n    qc.cry(2*np.arccos(-1/np.sqrt(10)), 1, 0)\n    qc.ry(2*np.arccos(1/np.sqrt(3)), 1)\n    qc.ch(1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AAB2473C76F2F", "submission_order": 6, "result": "AC", "execution_time": "1999 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.swap(0, 1)\n    qc.swap(0, 1)\n    qc.x(1)\n    qc.cx(1, 0)\n    qc.x(1)\n    qc.cry(2*np.arccos(2/3), 0, 1)\n    qc.cry(2*np.arccos(-1/np.sqrt(10)), 1, 0)\n    qc.ry(2*np.arccos(1/np.sqrt(3)), 1)\n    qc.ch(1, 0)\n    qc.swap(0, 1)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AABBAF707A884", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate, UnitaryGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # qc.x(1)\n    x = sqrt(1/3)\n    gate = UnitaryGate([[x, x, 0, -x], [0, x, -x, x], [x, 0, x, x], [x, -x, -x, 0]], check_input=True)\n    qc.append(gate.inverse(), [0, 1])\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AABBAF707A884", "submission_order": 2, "result": "WA", "execution_time": "1983 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    \"\"\"\n    x = sqrt(1/3)\n    gate = UnitaryGate([[x, x, 0, -x], [0, x, -x, x], [x, 0, x, x], [x, -x, -x, 0]], check_input=True)\n    qc.append(gate.inverse(), [0, 1])\n    return qc.decompose(reps=1)\n      ┌─────────────────────┐          ┌─────────────────┐                  ┌────────────┐       \nq_0: ─┤ U(π,-1.7459,2.9665) ├───■──────┤ U(2.3005,0,π/2) ├───────■──────────┤ U(π/2,0,0) ├───────\n     ┌┴─────────────────────┴┐┌─┴─┐┌───┴─────────────────┴────┐┌─┴─┐┌───────┴────────────┴──────┐\nq_1: ┤ U(1.5256,2.68,1.4803) ├┤ X ├┤ U(1.4702,1.4692,-3.1314) ├┤ X ├┤ U(2.6678,-0.22308,2.9424) ├\n     └───────────────────────┘└───┘└──────────────────────────┘└───┘└───────────────────────────┘\n\"\"\"\n    qc.u(pi, -1.7459, 2.9665, 0)\n    qc.u(1.5256, 2.68, 1.4803, 1)\n    qc.cx(0, 1)\n    qc.u(2.3005, 0, pi/2, 0)\n    qc.u(1.4702, 1.4692, -3.1314, 1)\n    qc.cx(0, 1)\n    qc.u(pi/2, 0, 0, 0)\n    qc.u(2.6678, -0.22308, 2.9424, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AABBAF707A884", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef find_solution():\n    from qiskit.circuit.library import UnitaryGate\n    x = sqrt(1/3)\n    gate = UnitaryGate([[x, x, 0, -x], [0, x, -x, x], [x, 0, x, x], [x, -x, -x, 0]], check_input=True)\n    qc = QuantumCircuit(2)\n    qc.append(gate.inverse(), [0, 1])\n    qc = qc.decompose()\n    for gate in qc._data:\n        print(gate)\n\"\"\"\n      ┌─────────────────────┐          ┌─────────────────┐                  ┌────────────┐       \nq_0: ─┤ U(π,-1.7459,2.9665) ├───■──────┤ U(2.3005,0,π/2) ├───────■──────────┤ U(π/2,0,0) ├───────\n     ┌┴─────────────────────┴┐┌─┴─┐┌───┴─────────────────┴────┐┌─┴─┐┌───────┴────────────┴──────┐\nq_1: ┤ U(1.5256,2.68,1.4803) ├┤ X ├┤ U(1.4702,1.4692,-3.1314) ├┤ X ├┤ U(2.6678,-0.22308,2.9424) ├\n     └───────────────────────┘└───┘└──────────────────────────┘└───┘└───────────────────────────┘\n\"\"\"\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.u(3.1415926535897927, -1.7459283308972953, 2.966460649487395, 0)\n    qc.u(1.5256421367586697, 2.679989861736903, 1.4803030618820676, 1)\n    qc.cx(0, 1)\n    qc.u(2.3005239830218636, 0.0, 1.5707963267948966, 0)\n    qc.u(1.4702087094713374, 1.4691752037207921, -3.1313531404558756, 1)\n    qc.cx(0, 1)\n    qc.u(pi/2, 0, 0, 0)\n    qc.u(2.6678334581465966, -0.22307720122877983, 2.9424024874858583, 1)\n\n    return qc\n    \n\ndef test():\n    from qiskit.quantum_info import Statevector\n    qc = solve()\n    \n    print(qc.depth())\n    sv = Statevector.from_instruction(qc)\n    print(sv)\n    print(sv.probabilities_dict())\n'''"}
{"problem": "QPC004_A6", "user": "AABBAF707A884", "submission_order": 4, "result": "WA", "execution_time": "1911 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef find_solution():\n    # from qiskit.circuit.library import UnitaryGate\n    x = sqrt(1/3)\n    gate = UnitaryGate([[x, x, 0, -x], [0, x, -x, x], [x, 0, x, x], [x, -x, -x, 0]], check_input=True)\n    qc = QuantumCircuit(2)\n    qc.append(gate.inverse(), [0, 1])\n    qc = qc.decompose()\n    for gate in qc._data:\n        print(gate)\n\"\"\"\n      ┌─────────────────────┐          ┌─────────────────┐                  ┌────────────┐       \nq_0: ─┤ U(π,-1.7459,2.9665) ├───■──────┤ U(2.3005,0,π/2) ├───────■──────────┤ U(π/2,0,0) ├───────\n     ┌┴─────────────────────┴┐┌─┴─┐┌───┴─────────────────┴────┐┌─┴─┐┌───────┴────────────┴──────┐\nq_1: ┤ U(1.5256,2.68,1.4803) ├┤ X ├┤ U(1.4702,1.4692,-3.1314) ├┤ X ├┤ U(2.6678,-0.22308,2.9424) ├\n     └───────────────────────┘└───┘└──────────────────────────┘└───┘└───────────────────────────┘\n\"\"\"\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    qc.u(3.1415926535897927, -1.7459283308972953, 2.966460649487395, 0)\n    qc.u(1.5256421367586697, 2.679989861736903, 1.4803030618820676, 1)\n    qc.cx(0, 1)\n    qc.u(2.3005239830218636, 0.0, 1.5707963267948966, 0)\n    qc.u(1.4702087094713374, 1.4691752037207921, -3.1313531404558756, 1)\n    qc.cx(0, 1)\n    qc.u(pi/2, 0, 0, 0)\n    qc.u(2.6678334581465966, -0.22307720122877983, 2.9424024874858583, 1)\n\n    return qc\n    \n\ndef test():\n    # from qiskit.quantum_info import Statevector\n    qc = solve()\n    \n    print(qc.depth())\n    sv = Statevector.from_instruction(qc)\n    print(sv)\n    print(sv.probabilities_dict())\n'''"}
{"problem": "QPC004_A6", "user": "AACB3B6354E03", "submission_order": 1, "result": "WA", "execution_time": "1903 ms", "memory": "161 MiB", "code": "'''python\nfrom math import acos\n\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    angle = 2 * acos(3 ** - 0.5)\n    qc.cry(angle, 0, 1)\n    qc.ch(1, 0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AB21B310AEB5A", "submission_order": 1, "result": "AC", "execution_time": "1654 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.x(0)\n    qc.ry(math.acos(1/math.sqrt(3))*2, 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.swap(0, 1)\n\n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_A6", "user": "AB4E87B9491CA", "submission_order": 1, "result": "RE", "execution_time": "1728 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    c0 = np.array([1, 1, 0, -1], dtype=complex) / math.sqrt(3)\n    c1 = np.array([-1, 2, 0,  1], dtype=complex) / math.sqrt(6)\n    c2 = np.array([1, 0, 1,  1], dtype=complex) / math.sqrt(3)\n    c3 = np.array([1, 0, -2, 1], dtype=complex) / math.sqrt(6)\n    U = np.column_stack([c0, c1, c2, c3])\n\n    gate = UnitaryGate(U, label=\"ZetaMoebius\")\n    qc.append(gate, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AB4E87B9491CA", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport math\nimport numpy as np\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    c0 = np.array([1, 1, 0, -1], dtype=complex) / math.sqrt(3)\n    c1 = np.array([-1, 2, 0,  1], dtype=complex) / math.sqrt(6)\n    c2 = np.array([1, 0, 1,  1], dtype=complex) / math.sqrt(3)\n    c3 = np.array([1, 0, -2, 1], dtype=complex) / math.sqrt(6)\n    U = np.column_stack([c0, c1, c2, c3])\n\n\n    gate = UnitaryGate(U, label=\"ZetaMoebius\")\n    qc.append(gate, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AB4E87B9491CA", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import UnitaryGate\n\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n\n    c0 = np.array([1, 1, 0, -1], dtype=complex) / math.sqrt(3)\n    c1 = np.array([-1, 2, 0,  1], dtype=complex) / math.sqrt(6)\n    c2 = np.array([1, 0, 1,  1], dtype=complex) / math.sqrt(3)\n    c3 = np.array([1, 0, -2, 1], dtype=complex) / math.sqrt(6)\n    U = np.column_stack([c0, c1, c2, c3])\n\n\n    gate = UnitaryGate(U, label=\"ZetaMoebius\")\n    qc.append(gate, [0, 1])\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AB4E87B9491CA", "submission_order": 4, "result": "AC", "execution_time": "1857 ms", "memory": "161 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n \n    theta = 2 * math.atan(math.sqrt(2))\n \n    qc.ry(theta, 1)\n    qc.ch(1, 0)\n    qc.cz(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "ABDC19E22EAB0", "submission_order": 1, "result": "AC", "execution_time": "1644 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    theta = math.atan(math.sqrt(2)) * 2\n\n    qc.ry(theta, 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AC82D2EB8895B", "submission_order": 1, "result": "AC", "execution_time": "2116 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2*math.acos(math.sqrt(2/3)), 1)\n    qc.x(0)\n    qc.cx(1,0)\n    qc.x(1)\n    qc.ch(1,0)\n    qc.x(1)\n    qc.cx(0,1)\n\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "ACFE380357E12", "submission_order": 1, "result": "RE", "execution_time": "1797 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.atan(math.sqrt(2)), 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(1, 0)  \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "ACFE380357E12", "submission_order": 2, "result": "RE", "execution_time": "1757 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.atan(math.sqrt(2)), 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(1, )  \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "ACFE380357E12", "submission_order": 3, "result": "AC", "execution_time": "1970 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.atan(math.sqrt(2)), 1)\n    qc.ch(1, 0)\n    qc.x(0)\n    qc.cx(0, 1)\n    qc.x(0)\n    qc.cz(1, 0)  \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AE182BD6CD638", "submission_order": 1, "result": "WA", "execution_time": "1822 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)  \n    qc.z(1) \n    qc.s(1)  \n    \n    qc.x(0) \n    qc.h(0) \n    qc.cx(0, 1)  \n    qc.s(0) \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AE182BD6CD638", "submission_order": 2, "result": "WA", "execution_time": "1973 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)  \n    qc.z(1) \n    qc.s(0)  \n    \n    qc.x(0) \n    qc.h(0) \n    qc.cx(0, 1)  \n    qc.s(0) \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AE182BD6CD638", "submission_order": 3, "result": "WA", "execution_time": "1882 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.h(0)  \n    qc.z(1) \n    \n    qc.x(0) \n    qc.h(0) \n    qc.cx(0, 1)  \n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AEA34DC7AA448", "submission_order": 1, "result": "RE", "execution_time": "1544 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cp(2 * math.atan(math.sqrt(2)),1)\n    qc.ch(1,0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AEA34DC7AA448", "submission_order": 2, "result": "RE", "execution_time": "1555 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cp(2 * math.atan(math.sqrt(2)),1)\n    qc.ch(1,0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cz(1,)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AEA34DC7AA448", "submission_order": 3, "result": "RE", "execution_time": "1520 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.cp(2 * math.atan(math.sqrt(2)),1)\n    qc.ch(1,0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AEA34DC7AA448", "submission_order": 4, "result": "AC", "execution_time": "1832 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n    # Write your code here:\n    qc.ry(2 * math.atan(math.sqrt(2)),1)\n    qc.ch(1,0)\n    qc.x(0)\n    qc.cx(0,1)\n    qc.x(0)\n    qc.cz(1,0)\n    return qc\n'''"}
{"problem": "QPC004_A6", "user": "AEB5FAA6C35C2", "submission_order": 1, "result": "AC", "execution_time": "2169 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2)\n\n    theta = 2 * np.arccos(1/np.sqrt(3))\n    qc.ry(theta, 1)\n\n    qc.ch(1,0)\n    qc.cx(0,1,ctrl_state=0)\n    qc.cz(1,0)\n\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A0147423327F7", "submission_order": 1, "result": "RE", "execution_time": "1465 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 1, "result": "WA", "execution_time": "1885 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 2, "result": "WA", "execution_time": "1567 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, XGate, ZGate\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    \n    # Apply Hadamard gates to first n qubits to create uniform superposition\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply controlled-phase gates to implement the transformation\n    for i in range(n):\n        for j in range(i + 1, n):\n            qc.cp(np.pi / 4, i, j)  # Controlled Phase to introduce subset relationships\n    \n    # Apply Möbius transform (alternating sum effect)\n    for i in range(n):\n        qc.z(i)  # Applying phase shift on first set\n        qc.cx(i, n + i)  # XOR to second set of qubits\n    \n    # Normalize by applying a global scaling factor (approximated with gates)\n    scale_factor = 1 / np.sqrt(3**n)  # Scaling by 1/sqrt(3^n)\n    qc.rz(np.arcsin(scale_factor), range(n))\n    \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create circuit with 2n qubits\n    qc = QuantumCircuit(2 * n)\n    \n    if n == 1:\n        # Apply Hadamard to create superposition\n        qc.h(0)\n        qc.h(1)\n        \n        # Apply controlled phase rotations\n        qc.cp(np.pi/3, 0, 1)\n        \n        # Apply additional gates for state transformation\n        qc.cx(0, 1)\n        qc.rz(np.pi/2, 1)\n        qc.h(0)\n        \n        # Final adjustments\n        qc.cx(1, 0)\n        qc.h(1)\n    else:\n        # For n > 1, we construct generalized transformation\n        # Apply initial layer of Hadamards\n        for i in range(2*n):\n            qc.h(i)\n            \n        # Apply controlled operations between pairs\n        for i in range(n):\n            qc.cp(np.pi/3, i, i+n)\n            \n        # Apply mixing operations\n        for i in range(n-1):\n            qc.cx(i, i+1)\n            qc.cp(np.pi/4, i, i+n)\n            \n        # Final layer of Hadamards\n        for i in range(2*n):\n            qc.h(i)\n    \n    return qc\nLast edited just now\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 4, "result": "WA", "execution_time": "1901 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create circuit with 2n qubits\n    qc = QuantumCircuit(2 * n)\n    \n    if n == 1:\n        # For n=1, implement the exact transformation shown in sample\n        # Starting state: a₀|00⟩ + a₁|10⟩\n        # Target: 1/√3[(a₀ + a₁)|00⟩ + a₁|10⟩ + a₀|01⟩ - (a₀ - a₁)|11⟩]\n        \n        # Create superposition\n        qc.ry(np.pi/3, 0)  # Angle for 1/√3 factor\n        \n        # Controlled operations\n        qc.cx(0, 1)\n        \n        # Phase adjustment\n        qc.rz(np.pi, 1)\n        \n        # Additional superposition\n        qc.ry(np.pi/4, 0)\n        qc.ry(np.pi/4, 1)\n    else:\n        # For n > 1, implement generalized transformation\n        for i in range(n):\n            # First layer: Create superpositions\n            qc.ry(np.pi/3, i)\n            \n            # Second layer: Controlled operations\n            qc.cx(i, i+n)\n            \n            # Third layer: Phase adjustments\n            qc.rz(np.pi/2, i+n)\n            \n            if i < n-1:  # Connect adjacent qubits except for last one\n                qc.cx(i, i+1)\n    \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 5, "result": "WA", "execution_time": "1586 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create circuit with 2n qubits\n    qc = QuantumCircuit(2 * n)\n    \n    if n == 1:\n        # Layer 1\n        qc.ry(np.pi/3, 0)\n        \n        # Layer 2\n        qc.cx(0, 1)\n        \n        # Layer 3\n        qc.rz(np.pi, 1)\n        qc.ry(np.pi/4, 0)\n        \n        # Layer 4\n        qc.ry(np.pi/4, 1)\n    else:\n        # Layer 1 - Initial rotations in parallel\n        for i in range(n):\n            qc.ry(np.pi/3, i)\n        \n        # Layer 2 - First set of CNOT in parallel\n        for i in range(0, n, 2):\n            if i+1 < n:\n                qc.cx(i, i+1)\n        \n        # Layer 3 - Second set of CNOT in parallel\n        for i in range(1, n, 2):\n            if i+1 < n:\n                qc.cx(i, i+1)\n        \n        # Layer 4 - Controlled operations between pairs\n        for i in range(n):\n            qc.cx(i, i+n)\n    \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 6, "result": "WA", "execution_time": "1591 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create circuit with 2n qubits\n    qc = QuantumCircuit(2 * n)\n    \n    if n == 1:\n        # Apply Hadamard to create superposition\n        qc.h(0)\n        qc.h(1)\n        \n        # Apply controlled phase rotations\n        qc.cp(np.pi/3, 0, 1)\n        \n        # Apply additional gates for state transformation\n        qc.cx(0, 1)\n        qc.rz(np.pi/2, 1)\n        qc.h(0)\n        \n        # Final adjustments\n        qc.cx(1, 0)\n        qc.h(1)\n    else:\n        # For n > 1, we construct generalized transformation\n        # Apply initial layer of Hadamards\n        for i in range(2*n):\n            qc.h(i)\n            \n        # Apply controlled operations between pairs\n        for i in range(n):\n            qc.cp(np.pi/3, i, i+n)\n            \n        # Apply mixing operations\n        for i in range(n-1):\n            qc.cx(i, i+1)\n            qc.cp(np.pi/4, i, i+n)\n            \n        # Final layer of Hadamards\n        for i in range(2*n):\n            qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 7, "result": "WA", "execution_time": "1575 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    \n    if n == 1:\n        # We need to transform: a₀|00⟩ + a₁|10⟩ to \n        # 1/√3[(a₀ + a₁)|00⟩ + a₁|10⟩ + a₀|01⟩ - (a₀ - a₁)|11⟩]\n        \n        # Layer 1: First transformation\n        qc.ry(2 * np.arccos(1/np.sqrt(3)), 0)\n        \n        # Layer 2: Create entanglement\n        qc.cx(0, 1)\n        \n        # Layer 3: Additional rotations\n        qc.rz(np.pi, 1)\n        \n        # Layer 4: Final adjustments\n        qc.ry(np.pi/2, 0)\n        qc.ry(np.pi/2, 1)\n    else:\n        # For general n > 1 case\n        # Layer 1: Initial rotations\n        for i in range(n):\n            qc.ry(2 * np.arccos(1/np.sqrt(3)), i)\n            \n        # Layer 2: Create entanglement pattern\n        for i in range(0, n-1, 2):\n            qc.cx(i, i+1)\n            \n        # Layer 3: Middle layer connections\n        for i in range(1, n-1, 2):\n            qc.cx(i, i+1)\n            \n        # Layer 4: Connect to second register\n        for i in range(n):\n            qc.cx(i, i+n)\n            \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 8, "result": "WA", "execution_time": "1564 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    \n    # Apply Hadamard gates to the first n qubits\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply controlled operations to create the desired transformation\n    for i in range(n):\n        qc.cx(i, n + i)\n        qc.cz(i, n + i)\n    \n    # Apply additional gates to achieve the required amplitudes and phases\n    for i in range(n):\n        qc.h(n + i)\n        qc.cx(i, n + i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 9, "result": "WA", "execution_time": "1668 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    \n    # Step 1: Apply Hadamard gates to the first n qubits to create superposition\n    for i in range(n):\n        qc.h(i)\n    \n    # Step 2: Implement the transformation for S ⊆ T ⊆ [n]\n    for i in range(n):\n        qc.cx(i, n + i)  # Controlled-X gate to copy subset information\n        qc.cz(i, n + i)  # Controlled-Z gate to introduce phase factors\n    \n    # Step 3: Implement the transformation for T ⊆ S ⊆ [n] with phase factors\n    for i in range(n):\n        qc.h(n + i)      # Hadamard gate on the second register\n        qc.cx(i, n + i)  # Controlled-X gate to enforce subset conditions\n    \n    # Step 4: Ensure the circuit depth does not exceed 8\n    # The above steps are designed to keep the depth within the limit\n    \n    return qc\n\n# Example usage:\nn = 1\nqc = solve(n)\nprint(qc)\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 10, "result": "WA", "execution_time": "2574 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    \n    # Apply Hadamard gates to the first n qubits to create superposition\n    for i in range(n):\n        qc.h(i)\n    \n    # Apply controlled operations to create the desired transformation\n    for i in range(n):\n        qc.cx(i, n + i)\n        qc.h(n + i)\n    \n    # Apply phase gates to introduce the (-1)^(|S| - |T|) factor\n    for i in range(n):\n        qc.cz(i, n + i)\n    \n    return qc\n\n# Example usage:\n# qc = solve(1)\n# print(qc)\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 11, "result": "WA", "execution_time": "1687 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create quantum circuit with 2*n qubits\n    qc = QuantumCircuit(2 * n)\n    \n    # For n=1 case, we need to implement:\n    # a₀|00⟩ + a₁|10⟩ → 1/√3{(a₀ + a₁)|00⟩ + a₁|10⟩ + a₀|01⟩ - (a₀ - a₁)|11⟩}\n    \n    if n == 1:\n        # First, create superposition with correct amplitudes\n        theta = np.arccos(1/np.sqrt(3))\n        qc.ry(2*theta, 0)\n        \n        # Add controlled operations for the second qubit\n        qc.cx(0, 1)\n        qc.x(0)\n        qc.cz(0, 1)\n        qc.x(0)\n        \n        # Adjust phases\n        qc.rz(np.pi, 1)\n        qc.cx(0, 1)\n    \n    # For n>1, we extend the transformation according to the general formula\n    else:\n        # Add gates for higher n values following the same pattern\n        # but extended to more qubits according to the formula\n        for i in range(n):\n            qc.ry(2*np.arccos(1/np.sqrt(3)), i)\n            qc.cx(i, i+n)\n    \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A47DA57BAA61C", "submission_order": 12, "result": "WA", "execution_time": "1588 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    # Create quantum circuit with 2n qubits\n    qc = QuantumCircuit(2 * n)\n    \n    if n == 1:\n        # Implement the transformation for n=1 case\n        \n        # First, create superposition using Hadamard gates\n        qc.h(0)\n        qc.h(1)\n        \n        # Apply controlled operations to achieve desired amplitudes\n        qc.cx(0, 1)\n        qc.rz(3.14159/2, 1)  # Phase rotation\n        qc.cx(0, 1)\n        \n        # Additional transformations to match required output state\n        qc.s(0)\n        qc.t(1)\n        \n        # Final Hadamard layer to complete transformation\n        qc.h(0)\n        qc.h(1)\n    \n    else:\n        # For n > 1, implement the general transformation\n        # First layer: Create initial superposition\n        for i in range(2*n):\n            qc.h(i)\n            \n        # Middle layers: Implement controlled operations\n        for i in range(n):\n            qc.cx(i, i+n)\n            qc.rz(3.14159/3, i+n)\n            qc.cx(i, i+n)\n            \n        # Final layer: Cleanup and normalization\n        for i in range(2*n):\n            qc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A53DCFE1533C9", "submission_order": 1, "result": "AC", "execution_time": "2486 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import sqrt, acos\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(2 * n)\n\tfor i in range(n):\n\t\tqc.swap(i, i + n)\n\t\tqc.ry(2 * acos(1 / sqrt(3)), i)\n\t\tqc.x(i + n)\n\t\tqc.ch(i, i + n)\n\t\tqc.x(i + n)\n\t\tqc.cx(i + n, i)\n\t\tqc.x(i + n)\n\treturn qc\n'''"}
{"problem": "QPC004_A7", "user": "A59D26C1912E2", "submission_order": 1, "result": "AC", "execution_time": "2049 ms", "memory": "160 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n \n    theta = 2 * math.atan(math.sqrt(2))\n \n    for i in range(n):\n        qc.ry(theta, i + n)\n        qc.ch(n + i, i)\n        qc.x(i)\n        qc.cx(i, n + i)\n        qc.x(i)\n        qc.cz(n + i, i)\n \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A6729B9FB9CB8", "submission_order": 1, "result": "RE", "execution_time": "1702 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * math.atan(math.sqrt(2)), i + n)\n        qc.ch(i + n, i)\n        qc.x(i)\n        qc.cx(i, i + n)\n        qc.x(i)\n        qc.cz(i + n, i)\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A6729B9FB9CB8", "submission_order": 2, "result": "AC", "execution_time": "1908 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * math.atan(math.sqrt(2)), i + n)\n        qc.ch(i + n, i)\n        qc.x(i)\n        qc.cx(i, i + n)\n        qc.x(i)\n        qc.cz(i + n, i)\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "A906AFD8D91D8", "submission_order": 1, "result": "AC", "execution_time": "2009 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * math.atan(math.sqrt(2)),i+n)\n        qc.ch(i+n,i)\n        qc.x(i)\n        qc.cx(i,i+n)\n        qc.x(i)\n        qc.cz(i+n,i)\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "ABF2349A4A64C", "submission_order": 1, "result": "RE", "execution_time": "2605 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    \n    # For n = 1, we have two qubits: q[0] for S and q[1] for the auxiliary state\n    if n == 1:\n        # Start with the state a_0 |00> + a_1 |10>\n        # Apply Hadamard to create superposition\n        qc.h(0)  # Create superposition on the first qubit\n        \n        # Apply controlled operations to create the required transformation\n        qc.cx(0, 1)  # Control from qubit 0 to qubit 1\n        \n        # Apply phase shifts to create the required amplitudes\n        qc.ry(math.pi / 3, 1)  # Apply a rotation to the second qubit\n        \n        # Apply a second controlled operation to create the negative amplitude\n        qc.cx(0, 1)  # Control from qubit 0 to qubit 1 again\n        \n        # Apply another rotation to adjust the phase\n        qc.ry(-math.pi / 3, 1)  # Apply a rotation to the second qubit\n        \n    # For n = 2, 3, 4, 5, we would extend this logic similarly\n    # However, for the sake of this example, we will only implement for n = 1\n    \n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "AD323CDCDBD86", "submission_order": 1, "result": "RE", "execution_time": "1841 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*math.acos(math.sqrt(2/3)), n+i)\n        qc.x(i)\n        qc.cx(n+i,i)\n        qc.x(n+i)\n        qc.ch(n+i,i)\n        qc.x(n+i)\n        qc.cx(i,n+i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "AD323CDCDBD86", "submission_order": 2, "result": "AC", "execution_time": "2032 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2*math.acos(math.sqrt(2/3)), n+i)\n        qc.x(i)\n        qc.cx(n+i,i)\n        qc.x(n+i)\n        qc.ch(n+i,i)\n        qc.x(n+i)\n        qc.cx(i,n+i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "AF0E08DDAFFEB", "submission_order": 1, "result": "WA", "execution_time": "1965 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n    for i in reversed(range(2*n-1)):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "AF10DE6C30D3F", "submission_order": 1, "result": "AC", "execution_time": "2060 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n    for i in range(n):\n        qc.ry(2 * math.atan(math.sqrt(2)), i + n)\n        qc.ch(i + n, i)\n        qc.x(i)\n        qc.cx(i, i + n)\n        qc.x(i)\n        qc.cz(i + n, i)\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "AFC6E854A0F1E", "submission_order": 1, "result": "WA", "execution_time": "1782 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\n\ndef make_control(g, bit):\n    return g if bit == 0 else g.control(bit)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    l = QuantumRegister(n)\n    r = QuantumRegister(n)\n    qc = QuantumCircuit(l, r)\n\n    theta = math.acos(math.sqrt(1 / 3)) * 2\n    qc.ry(theta, r)\n\n    for idx in range(n):\n        qc.ch(r[idx], l[idx])\n\n    for idx in range(n):\n        qc.cx(l[idx], r[idx])\n\n    qc.x(l)\n    for idx in range(n):\n        qc.swap(l[idx], r[idx])\n\n    qc.z(l)\n\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "AFC6E854A0F1E", "submission_order": 2, "result": "AC", "execution_time": "2120 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\n\ndef make_control(g, bit):\n    return g if bit == 0 else g.control(bit)\n\n\ndef solve(n: int) -> QuantumCircuit:\n    l = QuantumRegister(n)\n    r = QuantumRegister(n)\n    qc = QuantumCircuit(l, r)\n\n    theta = math.acos(math.sqrt(1 / 3)) * 2\n    qc.ry(theta, r)\n\n    qc.z(l)\n\n    for idx in range(n):\n        qc.ch(r[idx], l[idx])\n\n    for idx in range(n):\n        qc.cx(r[idx], l[idx])\n\n    qc.x(r)\n\n    for idx in range(n):\n        qc.cx(l[idx], r[idx])\n\n    qc.z(l)\n\n    return qc\n'''"}
{"problem": "QPC004_A7", "user": "AFF311CA54174", "submission_order": 1, "result": "AC", "execution_time": "2035 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2 * n)\n    # Write your code here:\n    for _ in range(n):\n        qc.ry(2 * math.atan(math.sqrt(2)),_+n)\n        qc.ch(_+n,_)\n        qc.x(_)\n        qc.cx(_,_+n)\n        qc.x(_)\n        qc.cz(_+n,_)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A00E61690AD66", "submission_order": 1, "result": "AC", "execution_time": "2151 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A0305FFE45A74", "submission_order": 1, "result": "AC", "execution_time": "2523 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    # Apply Hadamard gate to all qubits\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A04349FE5C1F6", "submission_order": 1, "result": "AC", "execution_time": "2455 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A07D6C961F8FC", "submission_order": 1, "result": "AC", "execution_time": "2141 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A0CF484007A19", "submission_order": 1, "result": "AC", "execution_time": "2469 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Apply Hadamard gate to each qubit\n    for qubit in range(n):\n        qc.h(qubit)\n    \n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A0E28BEADE1C6", "submission_order": 1, "result": "AC", "execution_time": "2139 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A151E0526A5EB", "submission_order": 1, "result": "WA", "execution_time": "1738 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A151E0526A5EB", "submission_order": 2, "result": "WA", "execution_time": "1848 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (n-1):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A151E0526A5EB", "submission_order": 3, "result": "WA", "execution_time": "1928 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range (0, n-1):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A151E0526A5EB", "submission_order": 4, "result": "AC", "execution_time": "1840 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A16209BE4A8F5", "submission_order": 1, "result": "AC", "execution_time": "1924 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A32F0E8AC8B5B", "submission_order": 1, "result": "AC", "execution_time": "2390 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A33A07E0FEEA9", "submission_order": 1, "result": "RE", "execution_time": "1574 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A33A07E0FEEA9", "submission_order": 2, "result": "AC", "execution_time": "1976 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A341DC0F0F0F8", "submission_order": 1, "result": "AC", "execution_time": "2065 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A3810C6732D17", "submission_order": 1, "result": "AC", "execution_time": "1917 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A41890BC3E673", "submission_order": 1, "result": "AC", "execution_time": "2419 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n) :\n        qc.h(i)\n        \n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A41D94895CD13", "submission_order": 1, "result": "RE", "execution_time": "1942 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n+1):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A41D94895CD13", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A4641E5959EC2", "submission_order": 1, "result": "AC", "execution_time": "2056 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n \n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A5159C61F000A", "submission_order": 1, "result": "AC", "execution_time": "2001 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A54CC303785E2", "submission_order": 1, "result": "AC", "execution_time": "2922 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A58AE28B86965", "submission_order": 1, "result": "AC", "execution_time": "2895 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A59F8D91C587B", "submission_order": 1, "result": "AC", "execution_time": "2106 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A5A10FA8AD8D9", "submission_order": 1, "result": "AC", "execution_time": "2704 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # n量子ビットすべてにHゲートを適用\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A5A782F1E5D1E", "submission_order": 1, "result": "RE", "execution_time": "2013 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n    qc.cx(0, [i for i in range(1,n)])\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A5A782F1E5D1E", "submission_order": 2, "result": "AC", "execution_time": "1957 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([i for i in range(n)])\n    if n>=2:\n        qc.cx(0, [i for i in range(1,n)])\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A5BA997E9140C", "submission_order": 1, "result": "AC", "execution_time": "1933 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A5C28EEEAC3BA", "submission_order": 1, "result": "AC", "execution_time": "1866 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A5ED6F3A4D676", "submission_order": 1, "result": "AC", "execution_time": "2374 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A62475E3496D9", "submission_order": 1, "result": "AC", "execution_time": "2057 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A6738364115B1", "submission_order": 1, "result": "AC", "execution_time": "2356 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A6B68D405A835", "submission_order": 1, "result": "AC", "execution_time": "2309 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A6BE5CF083B53", "submission_order": 1, "result": "AC", "execution_time": "2697 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A71919E658E58", "submission_order": 1, "result": "AC", "execution_time": "2131 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for n in range(n):\n        qc.h(n)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A73D3480C76DF", "submission_order": 1, "result": "AC", "execution_time": "2161 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A765F4208B839", "submission_order": 1, "result": "RE", "execution_time": "2338 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h([0, 1])\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A765F4208B839", "submission_order": 2, "result": "AC", "execution_time": "2088 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A797DC2D08F62", "submission_order": 1, "result": "AC", "execution_time": "1909 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in reversed(range(n)):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A83D2D4C69185", "submission_order": 1, "result": "AC", "execution_time": "2758 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A83E64B5BB1AE", "submission_order": 1, "result": "AC", "execution_time": "1890 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A899DB5B4DBEF", "submission_order": 1, "result": "AC", "execution_time": "2119 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n : int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A8BEBF12E7074", "submission_order": 1, "result": "AC", "execution_time": "2100 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A8EAC2656D7B3", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A952DE9DA3FF1", "submission_order": 1, "result": "AC", "execution_time": "2228 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A95E28AC15EB7", "submission_order": 1, "result": "AC", "execution_time": "2485 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A965ABFBACE2D", "submission_order": 1, "result": "AC", "execution_time": "2058 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A970679A8CFC7", "submission_order": 1, "result": "AC", "execution_time": "2008 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "A9711B243C3D5", "submission_order": 1, "result": "AC", "execution_time": "1976 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AA02142D08D7E", "submission_order": 1, "result": "AC", "execution_time": "1893 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AA44B8731FC43", "submission_order": 1, "result": "AC", "execution_time": "2432 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AAC6BA233A6F7", "submission_order": 1, "result": "AC", "execution_time": "2177 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# import matplotlib.pyplot\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(0, n):\n        qc.h(i)\n\n    return qc\n\n# solve(3).draw(\"mpl\")\n'''"}
{"problem": "QPC004_B1", "user": "AB44A9C6136F7", "submission_order": 1, "result": "AC", "execution_time": "1848 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AB49A9B73D607", "submission_order": 1, "result": "RE", "execution_time": "1592 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AB49A9B73D607", "submission_order": 2, "result": "RE", "execution_time": "1534 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AB540017AB11B", "submission_order": 1, "result": "AC", "execution_time": "2382 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AB85E1844ABA9", "submission_order": 1, "result": "AC", "execution_time": "2859 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ABD9646626616", "submission_order": 1, "result": "AC", "execution_time": "1908 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    \n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AC4BDCD9CE83A", "submission_order": 1, "result": "WA", "execution_time": "1826 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(0)\n    for i in range(n):\n        if (i != 0):\n            qc.cx(0, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AC4BDCD9CE83A", "submission_order": 2, "result": "AC", "execution_time": "1777 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AC4EDB7260592", "submission_order": 1, "result": "RE", "execution_time": "1728 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AC4EDB7260592", "submission_order": 2, "result": "AC", "execution_time": "2197 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AC94F4EA8EB74", "submission_order": 1, "result": "AC", "execution_time": "2681 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n          \t\n    for i in range(n):\n    \tqc.h(i)\n    \n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ACB2054F27CC5", "submission_order": 1, "result": "AC", "execution_time": "2047 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ACBE37508D590", "submission_order": 1, "result": "AC", "execution_time": "2129 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ACDB7CA5F9CC8", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ACDB7CA5F9CC8", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ACDB7CA5F9CC8", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ACDB7CA5F9CC8", "submission_order": 4, "result": "AC", "execution_time": "1720 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ACFE4428C6746", "submission_order": 1, "result": "AC", "execution_time": "2028 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AD223B0855C9B", "submission_order": 1, "result": "AC", "execution_time": "2017 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AD42C19D17BE9", "submission_order": 1, "result": "AC", "execution_time": "2072 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n \n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AD5E2B2183E89", "submission_order": 1, "result": "AC", "execution_time": "2301 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "ADB73E0D44B06", "submission_order": 1, "result": "AC", "execution_time": "1763 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_B1", "user": "ADB9103C516DE", "submission_order": 1, "result": "AC", "execution_time": "1981 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import sqrt, acos\n\ndef solve(n) -> QuantumCircuit:\n\tqc = QuantumCircuit(n)\n\tfor i in range(n):\n\t\tqc.h(i)\n\treturn qc\n'''"}
{"problem": "QPC004_B1", "user": "AE1FD22758033", "submission_order": 1, "result": "AC", "execution_time": "2017 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AE7441EF6D788", "submission_order": 1, "result": "AC", "execution_time": "2178 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for qubit in range(n):\n        qc.h(qubit)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AEAB6ED900CCA", "submission_order": 1, "result": "AC", "execution_time": "2004 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n      qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AF146CC179428", "submission_order": 1, "result": "AC", "execution_time": "2284 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AF830E9F0A890", "submission_order": 1, "result": "AC", "execution_time": "2083 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.h(range(n))\n\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AFAB2E38270CA", "submission_order": 1, "result": "WA", "execution_time": "1981 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AFAB2E38270CA", "submission_order": 2, "result": "WA", "execution_time": "1881 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n - 1):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B1", "user": "AFAB2E38270CA", "submission_order": 3, "result": "AC", "execution_time": "2011 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A041C787BADBE", "submission_order": 1, "result": "AC", "execution_time": "2288 ms", "memory": "162 MiB", "code": "'''python\nimport math\n\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0793838087BE", "submission_order": 1, "result": "WA", "execution_time": "1835 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0793838087BE", "submission_order": 2, "result": "WA", "execution_time": "1850 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cz(i, c)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0793838087BE", "submission_order": 3, "result": "WA", "execution_time": "1854 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.cz(k, c)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0793838087BE", "submission_order": 4, "result": "WA", "execution_time": "1981 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.cz(c, k)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0793838087BE", "submission_order": 5, "result": "AC", "execution_time": "2085 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range(n):\n        qc.cp(pi*2*a*2**i/2**n, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A093595FA92F1", "submission_order": 1, "result": "RE", "execution_time": "1616 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * k / 2**n\n        qc.cp(c, k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A093595FA92F1", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * k[i] / 2**n\n        qc.cp(c, k[])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A093595FA92F1", "submission_order": 3, "result": "RE", "execution_time": "1378 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(c, k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A093595FA92F1", "submission_order": 4, "result": "RE", "execution_time": "1547 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(c, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A093595FA92F1", "submission_order": 5, "result": "RE", "execution_time": "1775 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, c, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A093595FA92F1", "submission_order": 6, "result": "RE", "execution_time": "1636 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A093595FA92F1", "submission_order": 7, "result": "RE", "execution_time": "1414 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A093595FA92F1", "submission_order": 8, "result": "AC", "execution_time": "1924 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0AFE4DBCDA03", "submission_order": 1, "result": "RE", "execution_time": "1644 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for j in range(n):\n        angle = 2 * math.pi * a / (2 ** (n - j))\n        qc.crz(angle, c[0], k[j])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0AFE4DBCDA03", "submission_order": 2, "result": "WA", "execution_time": "1802 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for j in range(n):\n        angle = 2 * math.pi * a / (2 ** (n - j))\n        qc.crz(angle, c[0], k[j])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0AFE4DBCDA03", "submission_order": 3, "result": "WA", "execution_time": "1892 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for j in range(n):\n        angle = 2 * math.pi * a * (2 ** j) / (2 ** n)\n        qc.crz(angle, c[0], k[j])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A0C930D97F05E", "submission_order": 1, "result": "AC", "execution_time": "1899 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.cp(theta, c, k[idx])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A18B357103B68", "submission_order": 1, "result": "RE", "execution_time": "1445 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        angle = 2 * np.pi * a / (2 ** (k + 1))\n        qc.cp(angle, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A18B357103B68", "submission_order": 2, "result": "RE", "execution_time": "1585 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        angle = 2 * np.pi * a / (2 ** (k + 1))\n        qc.cp(angle, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A18B357103B68", "submission_order": 3, "result": "WA", "execution_time": "1536 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        angle = 2 * np.pi * a / (2 ** (n + 1))\n        qc.cp(angle, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A18B357103B68", "submission_order": 4, "result": "WA", "execution_time": "1600 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        angle = 2 * np.pi * a / (2 ** n)\n        qc.cp(angle, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A18B357103B68", "submission_order": 5, "result": "AC", "execution_time": "1857 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        angle = 2 * np.pi * a * (2 ** i) / (2 ** n)\n        qc.cp(angle, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A1DF48A294E05", "submission_order": 1, "result": "RE", "execution_time": "1561 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(pi/(2**(n - i)), n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A1DF48A294E05", "submission_order": 2, "result": "WA", "execution_time": "1780 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(pi/(2**(n - i)), n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A1DF48A294E05", "submission_order": 3, "result": "WA", "execution_time": "1840 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*pi/(2**(n - i)), n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A1DF48A294E05", "submission_order": 4, "result": "AC", "execution_time": "2321 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*a*pi/(2**(n - i)), n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A3CD632CB3206", "submission_order": 1, "result": "RE", "execution_time": "1589 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a / 2**(n-i), n, i)\n \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A3CD632CB3206", "submission_order": 2, "result": "AC", "execution_time": "2786 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    import math\n    for i in range(n):\n        qc.cp(2*math.pi*a / 2**(n-i), n, i)\n \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A3DD5B53D4651", "submission_order": 1, "result": "RE", "execution_time": "1891 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import PhaseGate\nimport math\n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.append(PhaseGate(2*math.pi*a/(2**(n-i))).control(i), [n])\n \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A3DD5B53D4651", "submission_order": 2, "result": "AC", "execution_time": "2434 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import PhaseGate\nimport math\n# from qiskit.quantum_info import Statevector\n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # init = [0]*(2**(n+1))\n    # init[2**n+1]=1\n    # qc.initialize(init)\n\n    # Write your code here:\n    for i in range(n):\n        qc.mcp(2*math.pi*a/(2**(n-i)), [n], i)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3, 1)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_B2", "user": "A46DFCB7BFB2D", "submission_order": 1, "result": "RE", "execution_time": "1811 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        a_k = (a >> i) & 1  \n        if a_k == 1:  \n            angle = 2 * math.pi * a_k / (2**n)\n            qc.cp(angle, k[i], c[0])\n    \n    qc.append([qc.cx(c[0], k[i]) for i in range(n)], k)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A46DFCB7BFB2D", "submission_order": 2, "result": "RE", "execution_time": "1788 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * k / 2**n\n        qc.p(theta, c, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A46DFCB7BFB2D", "submission_order": 3, "result": "WA", "execution_time": "1844 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**n  \n        qc.p(theta, k[i])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A46DFCB7BFB2D", "submission_order": 4, "result": "WA", "execution_time": "1891 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**n  \n        qc.cp(theta, c, k[i])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A46DFCB7BFB2D", "submission_order": 5, "result": "WA", "execution_time": "1982 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**n  \n\n        qc.cp(theta, c[0], k[i])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A46DFCB7BFB2D", "submission_order": 6, "result": "RE", "execution_time": "1688 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nimport qiskit.circuit.library as qulib\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = (2 * math.pi * a * i )/ 2**n  \n        cy_gate1 = qulib.RYGate(Theta).control(1,ctrl_state = '1')\n        qc.append(cy_gate1, [c, k[i]])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A4A1F64DE42A9", "submission_order": 1, "result": "AC", "execution_time": "2418 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        phase = 2 * np.pi * a * (2 ** i) / (2 ** n)\n        \n        qc.cp(phase, k[i], c[0])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A509995FC078A", "submission_order": 1, "result": "RE", "execution_time": "1814 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**n,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A509995FC078A", "submission_order": 2, "result": "RE", "execution_time": "1755 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate as PGate\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.append(PGate(2*math.pi*a/2**n).control(1), qargs=(i,n))\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A509995FC078A", "submission_order": 3, "result": "WA", "execution_time": "1884 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate as PGate\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.append(PGate(2*math.pi*a/2**n).control(1), qargs=(i,n))\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A509995FC078A", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate as PGate\nimport ma\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.append(PGate(2*math.pi*a/2**n).control(1), qargs=(n,i))\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A509995FC078A", "submission_order": 5, "result": "WA", "execution_time": "1900 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate as PGate\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.append(PGate(2*math.pi*a/2**n).control(1), qargs=(n,i))\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A509995FC078A", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate as PGate\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.append(PGate(2*math.pi*/2**(n-i)).control(1), qargs=(n,i))\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A509995FC078A", "submission_order": 7, "result": "AC", "execution_time": "1994 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate as PGate\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.append(PGate(2*math.pi*a/2**(n-i)).control(1), qargs=(n,i))\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 1, "result": "RE", "execution_time": "1643 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * i * a * k / 2**n\n        qc.p(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 2, "result": "RE", "execution_time": "1611 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # For each qubit in k, apply a controlled-phase (cp) gate.\n    for i in range(n):\n        # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n        angle = 2 * math.pi * a * (2**i) / (2**n)\n        # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n        qc.cp(angle, c[0], k[i])    \n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 3, "result": "RE", "execution_time": "1732 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # For each qubit in k, apply a controlled-phase (cp) gate.\n    for i in range(n):\n        # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n        angle = 2 * math.pi * a * i / (2**n)\n        # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n        qc.cp(angle, c[0], k[i])    \n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 4, "result": "RE", "execution_time": "1726 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # # For each qubit in k, apply a controlled-phase (cp) gate.\n    # for i in range(n):\n    #     # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n    #     angle = 2 * math.pi * a * i / (2**n)\n    #     # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n    #     qc.cp(angle, c[0], k[i])    \n\n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a * (2**i) / 2**n  # 位相シフト角度の計算\n        qc.cp(theta, k[i], c[0])  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 5, "result": "RE", "execution_time": "1908 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # # For each qubit in k, apply a controlled-phase (cp) gate.\n    # for i in range(n):\n    #     # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n    #     angle = 2 * math.pi * a * i / (2**n)\n    #     # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n    #     qc.cp(angle, c[0], k[i])    \n\n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a * (i) / 2**n  # 位相シフト角度の計算\n        qc.cp(theta, k[i], c[0])  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # # For each qubit in k, apply a controlled-phase (cp) gate.\n    # for i in range(n):\n    #     # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n    #     angle = 2 * math.pi * a * i / (2**n)\n    #     # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n    #     qc.cp(angle, c[0], k[i])    \n\n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a *  / 2**(n - i)  # 位相シフト角度の計算\n        qc.cp(theta, k[i], c[0])  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 7, "result": "RE", "execution_time": "1507 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # # For each qubit in k, apply a controlled-phase (cp) gate.\n    # for i in range(n):\n    #     # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n    #     angle = 2 * math.pi * a * i / (2**n)\n    #     # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n    #     qc.cp(angle, c[0], k[i])    \n\n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**(n)  # 位相シフト角度の計算\n        qc.cp(theta, k[i], c)  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 8, "result": "RE", "execution_time": "1689 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # # For each qubit in k, apply a controlled-phase (cp) gate.\n    # for i in range(n):\n    #     # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n    #     angle = 2 * math.pi * a * i / (2**n)\n    #     # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n    #     qc.cp(angle, c[0], k[i])    \n\n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**(n)  # 位相シフト角度の計算\n        qc.cp(theta, i, 1)  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 9, "result": "RE", "execution_time": "1531 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # # For each qubit in k, apply a controlled-phase (cp) gate.\n    # for i in range(n):\n    #     # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n    #     angle = 2 * math.pi * a * i / (2**n)\n    #     # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n    #     qc.cp(angle, c[0], k[i])    \n\n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**(n)  # 位相シフト角度の計算\n        qc.cp(theta, i, 0)  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 10, "result": "RE", "execution_time": "1772 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # # For each qubit in k, apply a controlled-phase (cp) gate.\n    # for i in range(n):\n    #     # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n    #     angle = 2 * math.pi * a * i / (2**n)\n    #     # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n    #     qc.cp(angle, c[0], k[i])    \n\n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**(n)  # 位相シフト角度の計算\n        qc.cp(theta, c[0], k[i])  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 11, "result": "RE", "execution_time": "1606 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # for i in range(n):\n    #     theta = 2 * math.pi * i *a * k / 2**n\n    #     qc.p(theta, i)\n\n    # # For each qubit in k, apply a controlled-phase (cp) gate.\n    # for i in range(n):\n    #     # Each qubit k[i] (which has weight 2^i) gets a phase shift:\n    #     angle = 2 * math.pi * a * i / (2**n)\n    #     # Apply the controlled phase gate: if c=1 and k[i]=1, then apply exp(i*angle)\n    #     qc.cp(angle, c[0], k[i])    \n\n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a * (2**i) / 2**(n)  # 位相シフト角度の計算\n        qc.cp(theta, c[0], k[i])  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 12, "result": "RE", "execution_time": "1942 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:  \n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        theta = 2 * math.pi * a * (2**i) / 2**n  # 位相シフト角度の計算\n        qc.cp(theta, c[0], k[i])  # 制御付き位相シフト\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A57BD588E6457", "submission_order": 13, "result": "WA", "execution_time": "1700 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:  \n\n    # 各 k のビット k_i に対して制御位相シフトを適用\n    for i in range(n):\n        # theta = 2 * math.pi * a * (2**i) / 2**n  # 位相シフト角度の計算\n        # qc.cp(theta, c[0], k[i])  # 制御付き位相シフト\n\n        if c == 1:\n            theta = 2 * math.pi * a * k / 2**n\n            qc.p(theta, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A63AA88460D2F", "submission_order": 1, "result": "WA", "execution_time": "1791 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range(n):\n        theta = 2 *  math.pi / 2**n * a\n        qc.cp(theta,n,i)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A63AA88460D2F", "submission_order": 2, "result": "WA", "execution_time": "1614 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    \n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A63AA88460D2F", "submission_order": 3, "result": "WA", "execution_time": "1977 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range(n):\n        theta = 2 * math.pi * 1 * a / 2**n\n        qc.p(theta,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A63AA88460D2F", "submission_order": 4, "result": "WA", "execution_time": "1793 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range(n):\n        theta = 2 * math.pi * 1 * a / 2**n\n        qc.cp(theta,c[0],k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A63AA88460D2F", "submission_order": 5, "result": "WA", "execution_time": "1719 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range(n):\n        theta = 2 * math.pi * 1 * a / 2**n\n        qc.p(theta,k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A63AA88460D2F", "submission_order": 6, "result": "WA", "execution_time": "1910 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range(n):\n        theta = 2 * math.pi * 1 * a / 2**n\n        qc.p(theta,k[i])\n    qc = QuantumCircuit(k, c)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A63AA88460D2F", "submission_order": 7, "result": "RE", "execution_time": "1783 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    for i in range(n):\n        theta = 2 * math.pi * 1 * a / 2**n\n        k.p(theta,i)\n    qc = QuantumCircuit(k, c)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A63AA88460D2F", "submission_order": 8, "result": "AC", "execution_time": "1926 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    p=math.pi\n    # Write your code here:\n    for i in range(n):\n        qc.cp(p*2**i/2**(n-1)*a,n,i)\n\n\n    return qc\nsolve(4,3).draw()\n'''"}
{"problem": "QPC004_B2", "user": "A6463F4716127", "submission_order": 1, "result": "RE", "execution_time": "1598 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * (a*k) / 2**n\n        qc.p(theta, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6463F4716127", "submission_order": 2, "result": "RE", "execution_time": "1920 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * (a*k) / 2**n\n        qc.p(theta, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6463F4716127", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport mat\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * (a*i) / 2**n\n        qc.p(theta, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6463F4716127", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport mat\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * (a*i*k) / 2**n\n        qc.p(theta, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6463F4716127", "submission_order": 5, "result": "RE", "execution_time": "1740 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * (a*i*k) / 2**n\n        qc.p(theta, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6728D5281BDF", "submission_order": 1, "result": "WA", "execution_time": "1898 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    import math\n    for j in range(1, n):\n        theta = 2 * math.pi * a * (2**(j-n))\n        qc.cp(theta,0,j)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6728D5281BDF", "submission_order": 2, "result": "WA", "execution_time": "1879 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    import math\n    for j in range(1,n+1):\n        theta = 2 * math.pi * a * (2**(j-n))\n        qc.cp(theta,0,j)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6728D5281BDF", "submission_order": 3, "result": "WA", "execution_time": "1794 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    import math\n    for j in range(1,n+1):\n        theta = 2 * math.pi * a * (2**(-n))\n        qc.cp(theta,0,j)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6728D5281BDF", "submission_order": 4, "result": "AC", "execution_time": "1889 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for j in range(n):\n        theta = (2 * 3.141592653589793 * a) / (2 ** (n - j))\n        qc.cp(theta, k[j], c[0])  # c を制御ビット、k[j] を対象ビットとして位相を適用\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6839A71066FF", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    \n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)).control(1), [n, i])\n \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A68B1F136C9AC", "submission_order": 1, "result": "WA", "execution_time": "2776 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n\n    for i in range(n):\n        angle = (2**i * a * 2* pi* i) / 2**n\n        qc.cp(angle, c[0], i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A68B1F136C9AC", "submission_order": 2, "result": "AC", "execution_time": "2142 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n\n    for i in range(n):\n        angle = (2* pi * 2**i * a ) / 2**n\n        qc.cp(angle, c[0], i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6D224A0F875F", "submission_order": 1, "result": "RE", "execution_time": "1794 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for k in range(n):\n        theta = 2 * math.pi * i * k * c * a / 2**n\n        qc.p(theta, k)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6D224A0F875F", "submission_order": 2, "result": "RE", "execution_time": "1661 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for k in range(n):\n        theta = 2 * math.pi * c * a * k/ 2**n\n        qc.p(theta, k)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6D224A0F875F", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = (2 * math.pi *  a / 2**n) 2**i\n        qc.cp(theta, c[0], k[i])\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6D224A0F875F", "submission_order": 4, "result": "RE", "execution_time": "1681 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = (2 * math.pi *  a / 2**n) * 2**i\n        qc.cp(theta, c[0], k[i])\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6D224A0F875F", "submission_order": 5, "result": "AC", "execution_time": "2210 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = (2 * math.pi *  a / 2**n) * 2**i\n        qc.cp(theta, -1, i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A6EB0AF7D8644", "submission_order": 1, "result": "AC", "execution_time": "2131 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for j in range(n):\n        theta=2*math.pi*a*(2**j)/(2**n)\n        qc.cp(theta,k[j],c[0])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A7555CBE259FD", "submission_order": 1, "result": "RE", "execution_time": "1710 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    for i in range(n):\n        theta = 2 * pi * a / 2**n\n        qc.cp(theta,n, i)\n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A7555CBE259FD", "submission_order": 2, "result": "WA", "execution_time": "1707 ms", "memory": "161 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    for i in range(n):\n        theta = 2 * pi * a / 2**n\n        qc.cp(theta,n, i)\n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A7555CBE259FD", "submission_order": 3, "result": "AC", "execution_time": "2100 ms", "memory": "163 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    for i in range(n):\n        theta = 2 * pi * a * 2**i / 2**n\n        qc.cp(theta,n, i)\n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 1, "result": "RE", "execution_time": "1644 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    k = QuantumRegister(n)  \n    c = QuantumRegister(1)  \n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n        qc.cp(2 * np.pi * a / (2**n), k[i], c[0]) \n    \n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 2, "result": "WA", "execution_time": "1919 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    k = QuantumRegister(n)  \n    c = QuantumRegister(1)  \n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n        qc.cp(2 * np.pi * a / (2**n), k[i], c[0]) \n    \n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 3, "result": "WA", "execution_time": "1941 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n, 'k')\n    c = QuantumRegister(1, 'c')\n    qc = QuantumCircuit(k, c)\n\n    for j in range(n):\n        for l in range(n - j):\n            phase = (a * 2**(l + j)) / (2**n)\n            qc.append(PhaseGate(2 * phase * 2**j), [k[l]])\n\n    for j in range(n):\n        qc.cx(k[j], c[0])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 4, "result": "WA", "execution_time": "1825 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n, 'k')\n    c = QuantumRegister(1, 'c')\n    qc = QuantumCircuit(k, c)\n\n    for j in range(n):\n        phase = (a * 2**j) / (2**n)\n        qc.append(PhaseGate(2 * phase), [k[j]])\n\n    for j in range(n):\n        qc.cx(k[j], c[0])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 5, "result": "WA", "execution_time": "1890 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n, 'k')\n    c = QuantumRegister(1, 'c')\n    qc = QuantumCircuit(k, c)\n\n    for j in range(n):\n        phase = (a * 2**j) / (2**n)\n        qc.append(PhaseGate(2 * phase * (2**(n-1-j))), [k[j]])\n\n    for j in range(n):\n        qc.cx(k[j], c[0])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 6, "result": "WA", "execution_time": "1848 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n, 'k')\n    c = QuantumRegister(1, 'c')\n    qc = QuantumCircuit(k, c)\n\n    for j in range(n):\n        phase = (a * 2**j) / (2**n)\n        qc.append(PhaseGate(2 * phase * (2**(n-1-j))), [k[j]])\n\n    for j in range(n):\n        qc.cx(k[j], c[0])\n        \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import PhaseGate\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n    qc.append(\n        qc.crz(2 * pi * a / (2**n), k[i], c[0]),  # 位相ゲート（制御付き）\n        [k[i], c[0]]\n    )\n\n        \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n    qc.append(\n        qc.crz(2 * pi * a / (2**n), k[i], c[0]),  # 位相ゲート（制御付き）\n        [k[i], c[0]]\n    )\n\n        \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 9, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n     for i in range(n):\n        qc.crz(2 * pi * a / (2**n), k[i], c[0])  # 位相ゲート（制御付き）\n\n\n        \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A76737D9E6673", "submission_order": 10, "result": "WA", "execution_time": "2097 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n        qc.crz(2 * pi * a / (2**n), k[i], c[0])  # 位相ゲート（制御付き）\n\n\n        \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A7EE5502F514F", "submission_order": 1, "result": "AC", "execution_time": "2091 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    theta  = math.pi*a\n    for i in range(n-1,-1,-1):\n        qc.cp(theta,i,n)\n        theta/=2\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A8ED6006EF7EA", "submission_order": 1, "result": "RE", "execution_time": "1574 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    # Create quantum registers and circuit\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    \n    # Calculate phase for each qubit position\n    for i in range(n):\n        # Phase is applied when k[i]=1 and c=1\n        # Phase angle for position i is: 2π * a * 2^i / 2^n = 2π * a * 2^(i-n)\n        angle = 2 * a * pow(2, i-n)  # Normalized by 2π\n        \n        # Controlled-controlled phase rotation\n        # Only apply phase when both k[i]=1 and c=1\n        qc.cp(2 * pi * angle, k[i], c[0])\n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A8ED6006EF7EA", "submission_order": 2, "result": "AC", "execution_time": "2049 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    # Create quantum registers for k and c\n    k = QuantumRegister(n)\n    c = QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    \n    # For each bit position in k\n    for i in range(n):\n        # Calculate phase angle: 2π * a * 2^i / 2^n\n        angle = 2 * pi * a * pow(2, i-n)\n        \n        # Apply controlled phase rotation\n        # Use controlled-phase gate between k[i] and c[0]\n        qc.cp(angle, k[i], c[0])\n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A951004B1C3AF", "submission_order": 1, "result": "AC", "execution_time": "2594 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tfor i in range(n):\n\t\tqc.cp(2 * a * pi / 2**n * 2**i, c, k[i])\n\treturn qc\n'''"}
{"problem": "QPC004_B2", "user": "A95F0B16D9518", "submission_order": 1, "result": "RE", "execution_time": "1851 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * S[i] / 2**m\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A95F0B16D9518", "submission_order": 2, "result": "RE", "execution_time": "1491 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * i / 2**m\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A95F0B16D9518", "submission_order": 3, "result": "RE", "execution_time": "1497 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**m\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A95F0B16D9518", "submission_order": 4, "result": "RE", "execution_time": "1544 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * i / 2**n\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A95F0B16D9518", "submission_order": 5, "result": "WA", "execution_time": "1924 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if (c == 1):\n            theta = 2 * math.pi * a * i / 2**n\n            qc.p(theta)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A95F0B16D9518", "submission_order": 6, "result": "RE", "execution_time": "1616 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if (c):\n            theta = 2 * math.pi * a * i / 2**n\n            qc.p(theta)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A95F0B16D9518", "submission_order": 7, "result": "RE", "execution_time": "1536 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if (c.measure()):\n            theta = 2 * math.pi * a * i / 2**n\n            qc.p(theta)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A9963837D7AE6", "submission_order": 1, "result": "AC", "execution_time": "2081 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n        angle = 2 * np.pi * a / (2 ** (n-i))\n        qc.cp(angle, i, n)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A99AE87E3C658", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    angle=2*np.pi*a*(2**n-1)/2**n\n    qc.rz(angle, n)\n    for i in range (n):\n        angle_i=2*np.pi*a*(2**(i)/2**n\n        qc.crz(angle_i, n, i) \n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A99AE87E3C658", "submission_order": 2, "result": "WA", "execution_time": "1617 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    angle=2*np.pi*a*(2**n-1)/2**n\n    qc.rz(angle, n)\n    for i in range (n):\n        angle_i=2*np.pi*a*2**(i)/2**n\n        qc.crz(angle_i, n, i) \n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A99AE87E3C658", "submission_order": 3, "result": "WA", "execution_time": "1735 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    angle=2*np.pi*a*(2**n-1)/2**n\n    qc.rz(angle, n)\n    for i in range (n):\n        angle_i=2*np.pi*a*2**(i)/2**n\n        qc.crz(angle_i, n, i) \n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A99AE87E3C658", "submission_order": 4, "result": "WA", "execution_time": "1629 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    angle=2*np.pi*a*(2**n-1)/2**n\n    qc.rz(angle, c[0])\n    for i in range (n):\n        angle_i=2*np.pi*a*2**(i)/2**n\n        qc.crz(angle_i, c[0], i) \n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A99AE87E3C658", "submission_order": 5, "result": "RE", "execution_time": "1744 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    angle=2*np.pi*a*(2**n-1)/2**n\n    qc.rz(angle*c[0], c[0])\n    for i in range (n):\n        angle_i=2*np.pi*a*2**(i)/2**n\n        qc.crz(angle_i, c[0], i) \n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A99AE87E3C658", "submission_order": 6, "result": "RE", "execution_time": "1665 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range (n):\n        angle_i=2*np.pi*a*2**(i)/2**n\n        qc.cp(n, angle_i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A99AE87E3C658", "submission_order": 7, "result": "RE", "execution_time": "1512 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library import CU1Gate\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range (n):\n        angle_i=2*np.pi*a*2**(i)/2**n\n        qc.cp(n, angle_i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A99AE87E3C658", "submission_order": 8, "result": "AC", "execution_time": "2077 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library import CU1Gate\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    for i in range (n):\n        angle_i=2*np.pi*a*2**(i)/2**n\n        qc.cp(angle_i, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A9CFC42737691", "submission_order": 1, "result": "RE", "execution_time": "1868 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * 2 ** i / 2 ** n\n        qc.cp(theta,n,i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A9CFC42737691", "submission_order": 2, "result": "AC", "execution_time": "2351 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a * 2 ** i / 2 ** n\n        qc.cp(theta,n,i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A9FC585F70810", "submission_order": 1, "result": "RE", "execution_time": "1987 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for _ in range(n):\n        qc.cp(math.pi * a * 2 ** (1-_-n),n,i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A9FC585F70810", "submission_order": 2, "result": "WA", "execution_time": "2287 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for _ in range(n):\n        qc.cp(math.pi * a * 2 ** (1-_-n),n,_)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "A9FC585F70810", "submission_order": 3, "result": "AC", "execution_time": "2395 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for _ in range(n):\n        qc.cp(2 * math.pi * a * 2 ** _ / 2 ** n,n,_)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AAD3D81DBABAB", "submission_order": 1, "result": "RE", "execution_time": "1694 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * np.pi * a / (2 ** (i - n))\n        qc.cp(theta, c[0], k[i])\n \n    return qc\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AAD3D81DBABAB", "submission_order": 2, "result": "RE", "execution_time": "1666 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * np.pi * a / (2 ** (i - n))\n        qc.cp(theta, c[0], k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AAD3D81DBABAB", "submission_order": 3, "result": "WA", "execution_time": "1880 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * np.pi * a / (2 ** (i - n))\n        qc.cp(theta, c[0], k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AAD3D81DBABAB", "submission_order": 4, "result": "AC", "execution_time": "1882 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2 * np.pi * a * 2 ** (i - n), c[0], k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AB5359488B09A", "submission_order": 1, "result": "RE", "execution_time": "1598 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2. * np.pi * a / (2 ** (i + 1)), c, k[i])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AB5359488B09A", "submission_order": 2, "result": "WA", "execution_time": "1622 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2. * np.pi * a / (2 ** (i + 1)), c, k[i])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AB5359488B09A", "submission_order": 3, "result": "AC", "execution_time": "2000 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2. * np.pi * a / (2 ** (n - i)), c, k[i])\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABA4C7D30507A", "submission_order": 1, "result": "RE", "execution_time": "1722 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = tau * a / (1 << n - i)\n        qc.crz(theta, c[0], k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABA4C7D30507A", "submission_order": 2, "result": "RE", "execution_time": "1738 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = tau * a / (1 << n - i)\n        qc.cp(theta, c[0], k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABA4C7D30507A", "submission_order": 3, "result": "AC", "execution_time": "1967 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import tau\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = tau * a / (1 << n - i)\n        qc.cp(theta, c[0], k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 1, "result": "RE", "execution_time": "1660 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    repetitions = 1\n    for counting_qubit in range(k):\n        for i in range(repetitions):\n            qpe.cp(math.pi/4, counting_qubit, 3);\n        repetitions *= 2\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 2, "result": "RE", "execution_time": "1558 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    repetitions = 1\n    for counting_qubit in range(k):\n        for i in range(repetitions):\n            qc.cp(math.pi/4, counting_qubit, 3);\n        repetitions *= 2\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 3, "result": "WA", "execution_time": "1823 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.p(theta, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 4, "result": "RE", "execution_time": "1549 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a *k / 2**n\n        qc.c(theta, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 5, "result": "WA", "execution_time": "1897 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a  / 2**n\n        qc.cp(theta, i, c)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 6, "result": "RE", "execution_time": "1631 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a  / 2**n\n        qc.cp(theta, i, n+1)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 7, "result": "WA", "execution_time": "1951 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a  / 2**n\n        qc.cp(theta, i, n)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 8, "result": "WA", "execution_time": "2094 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a  / 2**n\n        qc.cp(theta, i, n)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 9, "result": "RE", "execution_time": "1627 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * a  / 2**n\n        qc.cp(theta, i, 0)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 10, "result": "WA", "execution_time": "1820 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    repetitions = 1\n    for i in range(repetitions):\n        for i in range(n):\n            theta = 2 * math.pi * a  / 2**n\n            qc.cp(theta, i, c)\n        repetitions *= 2\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 11, "result": "WA", "execution_time": "1635 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    repetitions = 1\n    for k in range(repetitions):\n        for i in range(n):\n            theta = 2 * math.pi * a  / 2**n\n            qc.cp(theta, i, c)\n        repetitions *= 2\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 12, "result": "DLE", "execution_time": "1547 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    repetitions = 1\n    theta = 2 * math.pi * a  / 2**n\n    for i in range(n):\n        for k in range(repetitions):\n            qc.cp(theta, i, c)\n        repetitions *= 2\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABD8384219E76", "submission_order": 13, "result": "AC", "execution_time": "2036 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    repetitions = 1\n    \n    for i in range(n):\n        theta = 2 * math.pi * a * repetitions  / 2**n\n        qc.cp(theta, i, c)\n        repetitions *= 2\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABDF7E51FDEF5", "submission_order": 1, "result": "RE", "execution_time": "1612 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2*math.pi*a/(2**n)\n\n    for i in range(n):\n        qc.cphase(k[i], c, theta)\n        theta *= 2\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABDF7E51FDEF5", "submission_order": 2, "result": "RE", "execution_time": "1676 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2*math.pi*a/(2**n)\n\n    for i in range(n):\n        qc.cp(k[i], c, theta)\n        theta *= 2\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABDF7E51FDEF5", "submission_order": 3, "result": "RE", "execution_time": "1588 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2*math.pi*a/(2**n)\n\n    for i in range(n):\n        qc.c(theta, k[i], c)\n        theta *= 2\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "ABDF7E51FDEF5", "submission_order": 4, "result": "AC", "execution_time": "1876 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2*math.pi*a/(2**n)\n\n    for i in range(n):\n        qc.cp(theta, k[i], c)\n        theta *= 2\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AC5ED9B9286DD", "submission_order": 1, "result": "RE", "execution_time": "1644 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    for i in range(n):\n    \tt = 2 * math.pi * a * (2 ** i) / (2 ** n)\n    \tprint(i,t)\n    \tqc.cp(t,n,i)\n \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AC5ED9B9286DD", "submission_order": 2, "result": "RE", "execution_time": "1721 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    for i in range(n):\n    \tt = 2 * math.pi * a * (2 ** i) / (2 ** n)\n    \tqc.cp(t,n,i)\n \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AC5ED9B9286DD", "submission_order": 3, "result": "AC", "execution_time": "2038 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    import math    \n    if False:\n    \tisv = Statevector([1 if i == (1+8) else 0 for i in range(16)])\n    \tprint(isv)\n    \tqc.prepare_state(isv)\n    \n    for i in range(n):\n    \tt = 2 * math.pi * a * (2 ** i) / (2 ** n)\n    \tqc.cp(t,n,i)\n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AD73CCA548CBA", "submission_order": 1, "result": "WA", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for _ in range(n):\n        qc.cp(2 * n * a * 2 ** _ / 2 ** n,n,_)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AD73CCA548CBA", "submission_order": 2, "result": "AC", "execution_time": "2306 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for _ in range(n):\n        qc.cp(2 * math.pi * a * 2 ** _ / 2 ** n,n,_)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AE5270A14F50E", "submission_order": 1, "result": "WA", "execution_time": "1692 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for j in range(n):\n        theta_j = 2*math.pi * a * (2**j) / (2**n)\n        qc.crz(theta_j/2, k[j], c[0])\n        qc.cx(k[j], c[0])\n        qc.crz(-theta_j/2, k[j], c[0])\n        qc.cx(k[j], c[0])\n        qc.crz(theta_j/2, k[j], c[0])\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AE5270A14F50E", "submission_order": 2, "result": "DLE", "execution_time": "1590 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(qc: QuantumCircuit, qubits, inverse=False):\n    n = len(qubits)\n    if not inverse:\n        for j in range(n):\n            qc.h(qubits[j])\n            for m in range(j+1, n):\n                angle = math.pi / (2**(m-j))\n                qc.cp(angle, qubits[m], qubits[j])\n        # 最後にビット順を左右反転(SWAP)\n        for i in range(n//2):\n            qc.swap(qubits[i], qubits[n-1-i])\n    else:\n        for i in range(n//2):\n            qc.swap(qubits[i], qubits[n-1-i])\n        for j in reversed(range(n)):\n            for m in reversed(range(j+1, n)):\n                angle = - math.pi / (2**(m-j))\n                qc.cp(angle, qubits[m], qubits[j])\n            qc.h(qubits[j])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft(qc, k, inverse=False)\n\n    # 2) c=1 のとき，k[j] に位相 cp(θ_j)\n    #    θ_j = 2π a 2^j / 2^n\n    #    => sum_j θ_j * k_j = 2π a k / 2^n\n    for j in range(n):\n        theta_j = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(theta_j, c[0], k[j])\n\n    # 3) kに iQFT\n    qft(qc, k, inverse=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AE5270A14F50E", "submission_order": 3, "result": "RE", "execution_time": "1506 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft_butterfly(qc, qubits, inverse=False):\n    \"\"\"\n    バタフライ構造のQFT/iQFT (リトルエンディアン) を簡潔に実装。\n      - qubits[0] が最下位ビット\n      - inverse=False で 順QFT\n      - inverse=True  で 逆QFT (iQFT)\n\n    通常のQFTより同時並列にcpをかける部分が多く、回路深さを削減できる。\n    \"\"\"\n    n = len(qubits)\n    if n <= 1:\n        return\n\n    # 1) ビット列を左右反転 (最下位<->最上位, ... )\n    for i in range(n // 2):\n        qc.swap(qubits[i], qubits[n - 1 - i])\n\n    # 2) バタフライ段階：段数 ~ log2(n)\n    sign = -1 if not inverse else +1\n    stage = 1\n    while (1 << stage) <= n:\n        size = 1 << stage\n        half = size >> 1\n        # sizeごとのブロックに分割して並列にcp\n        for start in range(0, n, size):\n            for i in range(half):\n                angle = sign * math.pi * i / half\n                if abs(angle) > 1e-15:\n                    qc.cp(angle, qubits[start + half + i], qubits[start + i])\n        stage += 1\n\n    # 3) 各ビットにH\n    for i in range(n):\n        qc.h(qubits[i])\n\n    # 順QFTの場合は最後に再びビット反転が必要だが\n    # ここでは最初にswap済みなので再度swapして元に戻す\n    if not inverse:\n        for i in range(n // 2):\n            qc.swap(qubits[i], qubits[n - 1 - i])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    リトルエンディアン:\n      k[0] が最下位ビット (2^0),\n      k[n-1] が最上位ビット (2^(n-1)).\n\n    c = 0 のとき位相なし,\n    c = 1 のとき exp(2πi a k / 2^n) を付与する。\n    \"\"\"\n    k = QuantumRegister(n, 'k')\n    c = QuantumRegister(1, 'c')\n    qc = QuantumCircuit(k, c)\n\n    # 1) QFT(k) --- バタフライ実装\n    qft_butterfly(qc, k, inverse=False)\n\n    # 2) c=1 のときにのみ位相 exp(i * 2π a 2^j / 2^n) を掛ける\n    #    ( j=0..n-1 を全並列で処理 => 深さわずかに +1 程度 )\n    for j in range(n):\n        angle = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(angle, c[0], k[j])\n\n    # 3) iQFT(k) --- バタフライ実装\n    qft_butterfly(qc, k, inverse=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AE5270A14F50E", "submission_order": 4, "result": "RE", "execution_time": "1647 ms", "memory": "158 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft_butterfly(qc: QuantumCircuit, qubits, inverse=False):\n    \"\"\"\n    バタフライ構造で QFT (inverse=False) または iQFT (inverse=True) を実装する。\n    リトルエンディアン想定で、qubits[0] が最下位ビット。\n\n    通常の O(n^2) QFT 実装より浅い深さで済むが、\n    ゲート数は変わらず O(n^2)。n<=10 程度なら十分。\n\n    ※ 位相ゲート cp() をバタフライの各ステージで並列に配置する。\n    \"\"\"\n    n = len(qubits)\n    if n <= 1:\n        return  # 1量子ビット以下なら何もしない\n\n    # 1) bitの並びを反転 (最下位<->最上位, ..., 交換)\n    #    順QFTなら最後にこれをするが、バタフライ実装では最初にやったほうが簡便\n    for i in range(n//2):\n        qc.swap(qubits[i], qubits[n-1-i])\n\n    # もし inverse=True (逆QFT) なら\n    #   QFT(|x>) = 1/sqrt(2^n) Σy e^{2πi xy/2^n}|y>\n    # を逆にする際、cpゲートの符号が逆になるだけ。\n    # 以下、\"angle = ±π/2^(...) or ±2π/2^(...)\" で符号を切り替える。\n    sign = -1.0 if not inverse else +1.0\n\n    # 2) バタフライ演算: log(n) 段のループ\n    #    ステージ s=1..log(n)\n    #    ブロックサイズ = 2^s\n    #    各ブロック内で \"半分の長さ\" にわたって制御位相 (cp) をかけていく\n    stage = 1\n    while (1 << stage) <= n:\n        block_size = 1 << stage  # 2^stage\n        half_size  = block_size >> 1\n\n        # ブロックの先頭位置を step\n        for start in range(0, n, block_size):\n            # start + i と start + i + half_size がペアになる\n            for i in range(half_size):\n                # A = qubits[start + i]\n                # B = qubits[start + i + half_size]\n                # ここで A, B をカップルにして制御位相をかける\n                angle = sign * math.pi / (block_size >> 1) * i\n                if abs(angle) > 1e-15:\n                    qc.cp(angle, qubits[start + i + half_size], qubits[start + i])\n\n        stage += 1\n\n    # 3) 各ビットにHをかける (parallel)\n    for i in range(n):\n        qc.h(qubits[i])\n\n    # inverse=True (iQFT) の場合、ここまでで完了。\n    # inverse=False (順QFT) の場合、さらにビット反転が必要だが\n    #   この実装では最初に swap を済ませているので不要。\n    #   ただしダミー的にもう一度 swap して元に戻したいなら最後にやってもOK。\n    if not inverse:\n        for i in range(n//2):\n            qc.swap(qubits[i], qubits[n-1-i])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    リトルエンディアン:\n      k[0] が最下位ビット\n    補助ビット c[0] を加え: c=0 のとき位相なし, c=1 のとき位相 2π a k / 2^n\n\n    回路深さを抑えるため:\n      1) \"バタフライ版QFT\" で k を変換 (深さ ≈ n log n)\n      2) 単制御位相を各ビットに一括してかける (深さ 1～2)\n      3) バタフライ版 iQFT (深さ ≈ n log n)\n    \"\"\"\n    k = QuantumRegister(n, 'k')  # n量子ビット\n    c = QuantumRegister(1, 'c')  # 1量子ビット\n    qc = QuantumCircuit(k, c)\n\n    # 1) QFT(k)\n    qft_butterfly(qc, k, inverse=False)\n\n    # 2) c=1 のときにだけ k[j] へ位相 cp(...) を掛ける\n    #    ただし QFT空間では k[j] が \"周波数ビット\" になっているので，\n    #    角度は 2π a * 2^j / 2^n\n    #    ここはすべて並列実行可能 => 深さ1～2程度\n    for j in range(n):\n        angle_j = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(angle_j, c[0], k[j])\n\n    # 3) iQFT(k)\n    qft_butterfly(qc, k, inverse=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AE5270A14F50E", "submission_order": 5, "result": "RE", "execution_time": "1844 ms", "memory": "161 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft_butterfly(qc, qubits, inverse=False):\n    \"\"\"\n    バタフライ構造のQFT/iQFT (リトルエンディアン) を簡潔に実装。\n      - qubits[0] が最下位ビット\n      - inverse=False で 順QFT\n      - inverse=True  で 逆QFT (iQFT)\n\n    通常のQFTより同時並列にcpをかける部分が多く、回路深さを削減できる。\n    \"\"\"\n    n = len(qubits)\n    if n <= 1:\n        return\n\n    # 1) ビット列を左右反転 (最下位<->最上位, ... )\n    for i in range(n // 2):\n        qc.swap(qubits[i], qubits[n - 1 - i])\n\n    # 2) バタフライ段階：段数 ~ log2(n)\n    sign = -1 if not inverse else +1\n    stage = 1\n    while (1 << stage) <= n:\n        size = 1 << stage\n        half = size >> 1\n        # sizeごとのブロックに分割して並列にcp\n        for start in range(0, n, size):\n            for i in range(half):\n                angle = sign * math.pi * i / half\n                if abs(angle) > 1e-15:\n                    qc.cp(angle, qubits[start + half + i], qubits[start + i])\n        stage += 1\n\n    # 3) 各ビットにH\n    for i in range(n):\n        qc.h(qubits[i])\n\n    # 順QFTの場合は最後に再びビット反転が必要だが\n    # ここでは最初にswap済みなので再度swapして元に戻す\n    if not inverse:\n        for i in range(n // 2):\n            qc.swap(qubits[i], qubits[n - 1 - i])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    リトルエンディアン:\n      k[0] が最下位ビット (2^0),\n      k[n-1] が最上位ビット (2^(n-1)).\n\n    c = 0 のとき位相なし,\n    c = 1 のとき exp(2πi a k / 2^n) を付与する。\n    \"\"\"\n    k = QuantumRegister(n, 'k')\n    c = QuantumRegister(1, 'c')\n    qc = QuantumCircuit(k, c)\n\n    # 1) QFT(k) --- バタフライ実装\n    qft_butterfly(qc, k, inverse=False)\n\n    # 2) c=1 のときにのみ位相 exp(i * 2π a 2^j / 2^n) を掛ける\n    #    ( j=0..n-1 を全並列で処理 => 深さわずかに +1 程度 )\n    for j in range(n):\n        angle = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(angle, c[0], k[j])\n\n    # 3) iQFT(k) --- バタフライ実装\n    qft_butterfly(qc, k, inverse=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AE5270A14F50E", "submission_order": 6, "result": "RE", "execution_time": "1748 ms", "memory": "157 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft_butterfly(qc: QuantumCircuit, qubits, inverse=False):\n    \"\"\"\n    バタフライ構造(QFT/iQFT) - リトルエンディアン対応。\n      - qubits[0] が最下位ビット\n      - inverse=False:  順QFT\n      - inverse=True :  逆QFT (iQFT)\n    通常のQFTより多くの cp を並列化できるため、回路深さを小さく抑えられる。\n    \"\"\"\n    n = len(qubits)\n    if n < 2:\n        return  # 1ビット以下なら何もしない\n\n    # (1) ビット反転: qubits[i] <-> qubits[n-1-i]\n    for i in range(n // 2):\n        qc.swap(qubits[i], qubits[n - 1 - i])\n\n    # (2) バタフライ段階：log(n) ステージ\n    #     各ステージで「ブロックサイズ = 2^stage」に分割し，\n    #     半分の長さ half について並列に cp を掛ける\n    sign = -1 if not inverse else +1\n    stage = 1\n    while (1 << stage) <= n:\n        size = 1 << stage       # 2^stage\n        half = size >> 1       # 2^(stage-1)\n        for start in range(0, n, size):\n            for i in range(half):\n                angle = sign * math.pi * i / half\n                if abs(angle) < 1e-15:\n                    continue\n                # cp(angle, qubits[start+half+i], qubits[start+i])\n                qc.cp(angle, qubits[start + half + i], qubits[start + i])\n        stage += 1\n\n    # (3) 各ビットに H\n    for i in range(n):\n        qc.h(qubits[i])\n\n    # 順QFTの場合、最後にビットを再び反転しておく\n    if not inverse:\n        for i in range(n // 2):\n            qc.swap(qubits[i], qubits[n - 1 - i])\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    0 <= k < 2^n, c in {0,1}:\n      |k>_n |c>  ---> exp(2πi * a * c * k / 2^n) |k>_n |c>\n\n    リトルエンディアン: k[0] が最下位ビット\n    回路深さを小さくするために「バタフライ版QFT -> 単制御位相 -> iQFT」の流れ。\n    \"\"\"\n    k = QuantumRegister(n)  # n量子ビット (k[0]がLSB)\n    c = QuantumRegister(1)  # 1量子ビット (制御)\n    qc = QuantumCircuit(k, c)\n\n    # 1) QFT(k)  [バタフライ構造で深さを抑える]\n    qft_butterfly(qc, k, inverse=False)\n\n    # 2) c=1 のときにだけ位相 exp(i * 2π a 2^j / 2^n) をかける\n    #    ( j=0..n-1 を並列に適用 => 深さは +1～2程度 )\n    for j in range(n):\n        theta_j = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(theta_j, c[0], k[j])\n\n    # 3) iQFT(k)\n    qft_butterfly(qc, k, inverse=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AE5270A14F50E", "submission_order": 7, "result": "WA", "execution_time": "1825 ms", "memory": "162 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft_butterfly(qc: QuantumCircuit, qubits, inverse=False):\n    \"\"\"\n    バタフライ構造のQFT/iQFT (リトルエンディアン):\n      - qubits[0]が最下位ビット\n      - inverse=False -> 順QFT\n      - inverse=True  -> 逆QFT (iQFT)\n    回路深さを小さくしつつ、n=2等の小規模でも安全に動作するよう調整。\n    \"\"\"\n    n = len(qubits)\n    if n <= 1:\n        # 1量子ビット以下なら何もしない\n        if n == 1:\n            qc.h(qubits[0])\n        return\n\n    #\n    # (1) ビット反転: qubits[i] <-> qubits[n-1-i]\n    #\n    for i in range(n // 2):\n        qc.swap(qubits[i], qubits[n - 1 - i])\n\n    #\n    # (2) バタフライ段階\n    #\n    sign = -1.0 if not inverse else +1.0\n    stage = 1\n    while (1 << stage) <= n:\n        size = 1 << stage  # 2^stage\n        if size > n:\n            break  # 範囲外を避けるためスキップ\n        half = size >> 1   # 2^(stage-1)\n\n        # ブロックを size ごとに切って並列実行\n        for start in range(0, n, size):\n            # block: [start .. start+size-1]\n            # 前半: [start .. start+half-1]\n            # 後半: [start+half .. start+size-1]\n            # バタフライカーネル\n            for i in range(half):\n                # 後半 = (start+half+i), 前半 = (start+i)\n                idxA = start + i\n                idxB = start + half + i\n                if idxA >= n or idxB >= n:\n                    continue\n\n                angle = sign * math.pi * i / half\n                # angle=0 のときcpしても位相が0なのでスキップ\n                if abs(angle) < 1e-15:\n                    continue\n\n                qc.cp(angle, qubits[idxB], qubits[idxA])\n\n        stage += 1\n\n    #\n    # (3) 各ビットに H\n    #\n    for i in range(n):\n        qc.h(qubits[i])\n\n    #\n    # (4) 順QFTなら最後にもう一度ビット反転\n    #\n    if not inverse:\n        for i in range(n // 2):\n            qc.swap(qubits[i], qubits[n - 1 - i])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    問題:\n      0 <= k < 2^n, c in {0,1} に対し\n        |k>_n |c> -> exp(2πi * a * c * k / 2^n) |k>_n |c>\n    リトルエンディアン( k[0] が最下位ビット )想定。\n    バタフライ版QFTで回路深さを削減しつつ、位相を付与。\n    \"\"\"\n    k = QuantumRegister(n)  # n量子ビット (k[0]がLSB)\n    c = QuantumRegister(1)  # 1量子ビット (制御)\n    qc = QuantumCircuit(k, c)\n\n    # 1) QFT(k)\n    qft_butterfly(qc, k, inverse=False)\n\n    # 2) c=1 のとき k[j] に位相 2π a 2^j / 2^n を付与 (並列にcp)\n    for j in range(n):\n        theta_j = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(theta_j, c[0], k[j])\n\n    # 3) iQFT(k)\n    qft_butterfly(qc, k, inverse=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AE5270A14F50E", "submission_order": 8, "result": "AC", "execution_time": "2154 ms", "memory": "162 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for j in range(n):\n        theta_j = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(theta_j, c[0], k[j])\n \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AEA6C2755E52B", "submission_order": 1, "result": "DLE", "execution_time": "1868 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    \n    # Iterate over all possible values of k (0 to 2^n - 1)\n    for k_value in range(2**n):\n        # Calculate the phase shift angle\n        phase_shift = (2 * math.pi * a * k_value) / (2**n)\n        \n        # Apply the controlled phase shift if c is 1\n        # We use the `cp` gate for controlled phase shift\n        qc.cp(phase_shift, c[0], k)  # c[0] controls the phase shift on all k qubits\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AEA6C2755E52B", "submission_order": 2, "result": "RE", "execution_time": "2075 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    \n    for k_val in range(2**n):\n        qc.u1(2 * math.pi * a * k_val / 2**n, k)\n    \n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 1, "result": "RE", "execution_time": "1484 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        phase = 2 * math.pi * a * (2**i) / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 2, "result": "RE", "execution_time": "1668 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        phase = 2 * math.pi * a / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 3, "result": "RE", "execution_time": "1659 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        phase = 2 * math.pi * a * (2**(n-1-i)) / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 4, "result": "RE", "execution_time": "1717 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        phase = 2 * math.pi * a * (2**(n-1-i)) / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 5, "result": "RE", "execution_time": "1529 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        phase = 2 * math.pi * a * (2**(n-i)) / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 6, "result": "RE", "execution_time": "1647 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        phase = 2 * math.pi * a * (2**(n-i)) / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 7, "result": "RE", "execution_time": "1576 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        phase = 2 * math.pi * a * (2**(i+1)) / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 8, "result": "RE", "execution_time": "1601 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        phase = 2 * math.pi * a * (2**(i+1)) / (2**n)\n        qc.p(phase, i)\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 9, "result": "RE", "execution_time": "1502 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    for i in range(n-1, 0, -1):\n        qc.swap(qc, i, i-1)\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i+1)) / (2**n)\n        qc.cp(phase, i+1, i)\n    phase = 2 * math.pi * a * (2**n) / (2**n)\n    for i in range(0, n-1):\n        qc.swap(qc, i, i+1)\n    qc.cp(phase, 0, n-1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 10, "result": "RE", "execution_time": "1586 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i+1)) / (2**n)\n        qc.cp(phase, i+1, i)\n    phase = 2 * math.pi * a * (2**n) / (2**n)\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n    qc.cp(phase, 0, n-1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\nsolve(3, 2).draw()\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 11, "result": "RE", "execution_time": "1703 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i+1)) / (2**n)\n        qc.cp(phase, i+1, i)\n    phase = 2 * math.pi * a * (2**n) / (2**n)\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n    qc.cp(phase, 0, n-1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 12, "result": "RE", "execution_time": "1582 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    \n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i+1)) / (2**n)\n        qc.cp(phase, i+1, i)\n    phase = 2 * math.pi * a * (2**n) / (2**n)\n    qc.cp(phase, 0, n-1)\n\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 13, "result": "RE", "execution_time": "1737 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    \n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i)) / (2**n)\n        qc.cp(phase, i+1, i)\n    phase = 2 * math.pi * a * (2**(n-1)) / (2**n)\n    qc.cp(phase, 0, n-1)\n\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 14, "result": "RE", "execution_time": "1769 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(n-i)) / (2**n)\n        qc.cp(phase, i+1, i)\n    phase = 2 * math.pi * a * (2**(n-n+1)) / (2**n)\n    qc.cp(phase, 0, n-1)\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n    qc.draw()\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 15, "result": "RE", "execution_time": "1811 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(n-i+1)) / (2**n)\n        qc.cp(phase, i+1, i)\n    phase = 2 * math.pi * a * (2**(n-n+1)) / (2**n)\n    qc.cp(phase, 0, n-1)\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n    qc.draw()\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 16, "result": "RE", "execution_time": "1865 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    \n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i+1)) / (2**n)\n        qc.h(i+1)\n        qc.cp(phase, i+1, i)\n        qc.h(i+1)\n    phase = 2 * math.pi * a * (2**n) / (2**n)\n    qc.h(n-1)    \n    qc.cp(phase, 0, n-1)\n    qc.h(n-1)\n\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n    qc.draw()\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 17, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    \n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i)) / (2**n)\n        qc.h(i+1)\n        qc.cp(phase, i+1, i)\n        qc.h(i+1)\n    phase = 2 * math.pi * a * (2**(n-1)) / (2**n)\n    qc.h(n-1)    \n    qc.cp(phase, 0, n-1)\n    qc.h(n-)\n\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n    qc.draw()\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 18, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    \n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i)) / (2**n)\n        qc.h(i+1)\n        qc.cp(phase, i+1, i)\n        qc.h(i+1)\n    phase = 2 * math.pi * a * (2**(n-)) / (2**n)\n    qc.h(n-1)    \n    qc.cp(phase, 0, n-1)\n    qc.h(n-)\n\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 19, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    \n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i)) / (2**n)\n        qc.h(i+1)\n        qc.cp(phase, i+1, i)\n        qc.h(i+1)\n    phase = 2 * math.pi * a * (2**(n-)) / (2**n)\n    qc.h(0)    \n    qc.cp(phase, 0, n-1)\n    qc.h(0)\n\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 20, "result": "RE", "execution_time": "1496 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    \n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(i+1)) / (2**n)\n        qc.h(i+1)\n        qc.cp(phase, i+1, i)\n        qc.h(i+1)\n    phase = 2 * math.pi * a * (2**(n)) / (2**n)\n    qc.h(0)    \n    qc.cp(phase, 0, n-1)\n    qc.h(0)\n\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 21, "result": "RE", "execution_time": "1754 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef oracle(n, a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1, 0, -1):\n        qc.swap(i, i-1)\n    \n    for i in range(n-1):\n        phase = 2 * math.pi * a * (2**(n-i-1)) / (2**n)\n        qc.h(i+1)\n        qc.cp(phase, i+1, i)\n        qc.h(i+1)\n    phase = 2 * math.pi * a * (2**(n-n+1)) / (2**n)\n    qc.h(0)    \n    qc.cp(phase, 0, n-1)\n    qc.h(0)\n\n    for i in range(0, n-1):\n        qc.swap(i, i+1)\n\n    return qc.to_gate().control(1)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    oracle_gate = oracle(n, a)\n    qbits = []\n    qbits.append(n)\n    for i in range(0, n):\n        qbits.append(i)\n    qc.append(oracle_gate, qbits)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 22, "result": "RE", "execution_time": "1946 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(0, n):\n        phase = 2 * math.pi * a * (2**i) / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF2DE78B41C6F", "submission_order": 23, "result": "AC", "execution_time": "1963 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(0, n):\n        phase = 2 * math.pi * a * (2**i) / (2**n)\n        qc.cp(phase, n, i)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF3E30B088F41", "submission_order": 1, "result": "WA", "execution_time": "2206 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a * (2 ** i)  / (2 ** n)\n        qc.cry(theta, k[i], c)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF3E30B088F41", "submission_order": 2, "result": "AC", "execution_time": "2887 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a * (2 ** i)  / (2 ** n)\n        qc.cp(theta, k[i], c)\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 1, "result": "RE", "execution_time": "1652 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, i, n+1)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 2, "result": "RE", "execution_time": "1762 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, n+1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 3, "result": "RE", "execution_time": "1652 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 4, "result": "RE", "execution_time": "1705 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, c[1], i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 5, "result": "RE", "execution_time": "1766 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, c[0], i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 6, "result": "RE", "execution_time": "1459 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 7, "result": "RE", "execution_time": "1615 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta, i,n)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 8, "result": "RE", "execution_time": "1758 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 9, "result": "RE", "execution_time": "1437 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n+1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 10, "result": "RE", "execution_time": "1603 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n-1,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 11, "result": "RE", "execution_time": "1628 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,qc[n],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 12, "result": "RE", "execution_time": "2009 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 13, "result": "RE", "execution_time": "1558 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 14, "result": "RE", "execution_time": "1603 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 15, "result": "RE", "execution_time": "1759 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 16, "result": "RE", "execution_time": "1488 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 17, "result": "RE", "execution_time": "1733 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,c[1],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 18, "result": "RE", "execution_time": "1543 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 19, "result": "RE", "execution_time": "1540 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 20, "result": "RE", "execution_time": "1881 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(k):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 21, "result": "RE", "execution_time": "1561 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(k):\n        theta = 2 * math.pi * a / 2**k\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 22, "result": "RE", "execution_time": "1646 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 23, "result": "RE", "execution_time": "1717 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * a / 2**n\n        qc.cp(theta,i,n)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 24, "result": "RE", "execution_time": "1837 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    theta = 2 * math.pi * a / 2**n\n    for i in range(n):\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 25, "result": "RE", "execution_time": "1681 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    theta = 2 * math.pi * a / 2**n\n    for i in range(n):\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 26, "result": "RE", "execution_time": "1632 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    theta = 2 * math.pi * a / 2**n\n    for i in range(n):\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 27, "result": "RE", "execution_time": "1590 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 28, "result": "RE", "execution_time": "1742 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        theta = 2 * math.pi * a *2**i / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 29, "result": "RE", "execution_time": "1696 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 30, "result": "RE", "execution_time": "1774 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        theta = (2 * math.pi * a * 2**i) / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 31, "result": "RE", "execution_time": "1737 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        theta = (2 * math.pi * a * 2**(n-i)) / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 32, "result": "RE", "execution_time": "1622 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        theta = (2 * math.pi * a * 2**(n-i-1)) / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 33, "result": "RE", "execution_time": "1632 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        theta = (2 * math.pi * a * 2**(i)) / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 34, "result": "RE", "execution_time": "1771 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        theta = (2 * math.pi * a * 2**(i+1)) / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 35, "result": "RE", "execution_time": "1821 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    theta = 2 * math.pi * a / 2**n\n\n    for i in range(n):\n        theta = (2 * math.pi * a * 2**i) / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 36, "result": "RE", "execution_time": "1904 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n\n    for i in range(n):\n        theta = (2 * math.pi * a * 2**i) / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 37, "result": "RE", "execution_time": "1553 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 38, "result": "RE", "execution_time": "1623 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(n+1)\n    # Write your code here:\n\n\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 39, "result": "RE", "execution_time": "1534 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k,c)\n    # Write your code here:\n\n\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta,c[0],i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 40, "result": "RE", "execution_time": "1593 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k,c)\n    # Write your code here:\n\n\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 41, "result": "RE", "execution_time": "1656 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    #k, c = QuantumRegister(n), QuantumRegister(1)\n    #qc = QuantumCircuit(k,c)\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n\n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta,n,i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 42, "result": "RE", "execution_time": "1603 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    #k, c = QuantumRegister(n), QuantumRegister(1)\n    #qc = QuantumCircuit(k,c)\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 43, "result": "RE", "execution_time": "1500 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k,c)\n    # Write your code here:\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AF95927B7CA88", "submission_order": 44, "result": "AC", "execution_time": "2257 ms", "memory": "162 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k,c)\n    # Write your code here:\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B2", "user": "AFF75B7A1E312", "submission_order": 1, "result": "AC", "execution_time": "2513 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A11896B000A31", "submission_order": 1, "result": "RE", "execution_time": "1894 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n) \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi/(2**(i-j)), j, i)\n    for i in range(n//2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.compose(QFT(n), k, inplace = True)\n    a_list = [(a//(2**i))%2 for i in range(n)]\n    for i in range(n):\n      qc.cp(2*pi*a_list[i]/(2**(n - i)), n, i)\n    qc.compose(QFT(n).inverse(), k, inplace = True)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A11896B000A31", "submission_order": 2, "result": "RE", "execution_time": "1506 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n) \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi/(2**(i-j)), j, i)\n    for i in range(n//2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.compose(QFT(n), k, inplace = True)\n    a_list = [(a//(2**i))%2 for i in range(n)]\n    for i in range(n):\n        qc.cp(2*pi*a_list[i]/(2**(n - i)), n, i)\n    qc.compose(QFT(n).inverse(), k, inplace = True)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A11896B000A31", "submission_order": 3, "result": "RE", "execution_time": "1686 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n) \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi/(2**(i-j)), j, i)\n    for i in range(n//2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.compose(QFT(n), k, inplace = True)\n    a_list = [(a//(2**i))%2 for i in range(n)]\n    for i in range(n):\n        qc.cp(2*pi*a_list[i]/(2**(n - i)), n, i)\n    qc.compose(QFT(n).inverse(), k, inplace = True)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A11896B000A31", "submission_order": 4, "result": "RE", "execution_time": "1632 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef tmp(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n) \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi/(2**(i-j)), j, i)\n    for i in range(n//2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.compose(tmp(n), k, inplace = True)\n    a_list = [(a//(2**i))%2 for i in range(n)]\n    for i in range(n):\n        qc.cp(2*pi*a_list[i]/(2**(n - i)), n, i)\n    qc.compose(tmp(n).inverse(), k, inplace = True)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A152FFAB6B770", "submission_order": 1, "result": "AC", "execution_time": "2220 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import tau, pi\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(pi / (1 << (i - j)), j, i)\n\n    for i in range(n):\n        theta = tau / (1 << n - i)\n        # qc.cp(a * theta[i], k[n - 1 - i])\n        qc.cp(a * theta, c[0], k[n - 1 - i])\n\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-pi / (1 << (i - j)), j, i)\n        qc.h(i)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A2D27FB7ED6EA", "submission_order": 1, "result": "AC", "execution_time": "2950 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n# from qiskit.quantum_info import Statevector\n\ndef quantum_fourier_transform(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n-1, -1, -1):\n        qc.h(i)\n        for j in range(i-1, -1, -1):\n            qc.cp(2*math.pi/(2**(i-j+1)), j, i)\n    \n    i = 0\n    while i<n-i-1:\n        qc.swap(i, n-i-1)\n        i += 1\n    \n    return qc\n \ndef b2(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # init = [0]*(2**(n+1))\n    # init[2**n+1]=1\n    # qc.initialize(init)\n\n    # Write your code here:\n    for i in range(n):\n        qc.mcp(2*math.pi*a/(2**(n-i)), [n], i)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.compose(quantum_fourier_transform(n), k, inplace=True)\n    for i in range(n):\n        qc.mcp(2*math.pi*a/(2**(n-i)), [n], i)\n    qc.compose(quantum_fourier_transform(n).inverse(), k, inplace=True)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(3, 1)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC004_B3", "user": "A35C170FE5AC1", "submission_order": 1, "result": "WA", "execution_time": "1806 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if (a >> i) & 1: \n            qc.cx(c[0], k[i])  \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A35C170FE5AC1", "submission_order": 2, "result": "WA", "execution_time": "1802 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if (a >> i) & 1: \n            qc.cx(c[0], k[i]) \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A35C170FE5AC1", "submission_order": 3, "result": "RE", "execution_time": "1561 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # 補助レジスタ\n    carry = QuantumRegister(1, 'carry')\n    result = QuantumRegister(n, 'result')\n    qc.add_register(carry, result)\n\n    # cの値に応じてaを加算\n    for i in range(n):\n        qc.cx(c, k[i])\n\n    # k + a mod 2^n を計算\n    for i in range(n):\n        qc.ccx(k[i], carry, result[i])\n        qc.cx(k[i], carry)\n        qc.cx(carry, result[i])\n\n    # 結果をkレジスタにコピー\n    for i in range(n):\n        qc.cx(result[i], k[i])\n\n    # 補助レジスタをリセット\n    for i in range(n):\n        qc.cx(result[i], result[i])\n    qc.cx(carry, carry)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A35C170FE5AC1", "submission_order": 4, "result": "WA", "execution_time": "1761 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        # a の i 番目のビットが 1 の場合に制御加算\n        if (a >> i) & 1:\n            qc.cx(c, k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A35C170FE5AC1", "submission_order": 5, "result": "WA", "execution_time": "1966 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        if (a >> i) & 1:\n            qc.cx(c, k[i])\n    qc.barrier()\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A35C170FE5AC1", "submission_order": 6, "result": "WA", "execution_time": "2069 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n        if (a >> i) & 1:\n            qc.cx(k[i], k[(i + 1) % n])\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A35C170FE5AC1", "submission_order": 7, "result": "WA", "execution_time": "1686 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n    for i in range(n):\n        if (a >> i) & 1:\n            qc.cx(c, k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A3900E3AFAB4F", "submission_order": 1, "result": "AC", "execution_time": "2066 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.cp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A4D060D0F83CA", "submission_order": 1, "result": "WA", "execution_time": "2108 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        if (a & (1 << i)):\n            qc.cx(c[0], k[n - i - 1])\n            \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A4D060D0F83CA", "submission_order": 2, "result": "AC", "execution_time": "2096 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        if (a & (1 << i)):\n            print(i)\n            n_not = n - i\n            for j in range(i+n_not-1, i-1, -1):\n                qc.mcx(k[i:j] + [c[0]], k[j])\n            \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A63F29E56028A", "submission_order": 1, "result": "WA", "execution_time": "2194 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft_rotations(qc, n):\n    \"\"\"Apply QFT rotations to specified qubits\"\"\"\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(math.pi/float(2**(j-i)), j, i)\n\ndef inverse_qft_rotations(qc, n):\n    \"\"\"Apply inverse QFT rotations to specified qubits\"\"\"\n    for i in range(n-1, -1, -1):\n        for j in range(n-1, i, -1):\n            qc.cp(-math.pi/float(2**(j-i)), j, i)\n        qc.h(i)\n\ndef add_constant(qc, n, a, control):\n    \"\"\"Add constant a (controlled by control qubit) using phase rotations\"\"\"\n    for i in range(n):\n        angle = (2 * math.pi * (a / (2 ** (n-i)))) % (2 * math.pi)\n        if angle != 0:  # Only apply non-zero rotations\n            qc.cp(angle, control, i)\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    \n    # Apply QFT to register k\n    qft_rotations(qc, n)\n    \n    # Add constant a controlled by c\n    add_constant(qc, n, a, n)\n    \n    # Apply inverse QFT\n    inverse_qft_rotations(qc, n)\n    \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A63F29E56028A", "submission_order": 2, "result": "RE", "execution_time": "1832 ms", "memory": "159 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef manual_qft(n):\n    \"\"\"Manually implements the Quantum Fourier Transform (QFT).\"\"\"\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(np.pi / 2**(k - j), k, j)  # Controlled phase rotation\n    return qc\n\ndef manual_iqft(n):\n    \"\"\"Manually implements the Inverse Quantum Fourier Transform (IQFT).\"\"\"\n    return manual_qft(n).inverse()\n\ndef controlled_modular_addition(n, a):\n    \"\"\"Implements controlled modular addition using QFT & controlled phase shifts.\"\"\"\n    qc = QuantumCircuit(n + 1)  # Extra qubit for control\n\n    # Apply QFT to the lower n qubits (excluding control qubit)\n    qc.append(manual_qft(n), range(n))\n\n    # Apply controlled phase shifts based on the bits of 'a'\n    for i in range(n):\n        if (a >> i) & 1:  # Check if the i-th bit of 'a' is set\n            qc.cp(np.pi / 2**(n - i - 1), n, i)  # Apply controlled phase shift\n\n    # Apply inverse QFT\n    qc.append(manual_iqft(n), range(n))\n\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"Constructs the controlled modular addition circuit.\"\"\"\n    k_reg = QuantumRegister(n, name='k')  # Register for k\n    c_reg = QuantumRegister(1, name='c')  # Control qubit\n    qc = QuantumCircuit(k_reg, c_reg)\n\n    # Apply controlled modular addition only when c = 1\n    controlled_add = controlled_modular_addition(n, a).to_gate(label=\"C-ADD(a)\").control(1)\n    \n    # Apply controlled modular addition with explicit control\n    qc.append(controlled_add, [c_reg[0]] + k_reg[:])\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A63F29E56028A", "submission_order": 3, "result": "RE", "execution_time": "1858 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef controlled_modular_addition(n, a):\n    \"\"\"Implements controlled modular addition using bitwise operations.\"\"\"\n    qc = QuantumCircuit(n + 1)  # Extra qubit for control\n\n    for i in range(n):\n        if (a >> i) & 1:  # If the i-th bit of 'a' is 1\n            qc.cx(n, i)  # Controlled-X: If control is 1, flip bit i of 'k'\n    \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"Constructs an optimized controlled modular addition circuit.\"\"\"\n    k_reg = QuantumRegister(n, name='k')  # Register for k\n    c_reg = QuantumRegister(1, name='c')  # Control qubit\n    qc = QuantumCircuit(k_reg, c_reg)\n\n    # Apply controlled modular addition (bitwise controlled-X operations)\n    controlled_add = controlled_modular_addition(n, a).to_gate(label=\"C-ADD(a)\").control(1)\n    \n    qc.append(controlled_add, [c_reg[0]] + k_reg[:])\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A63F29E56028A", "submission_order": 4, "result": "WA", "execution_time": "2081 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n, 'k')\n    c = QuantumRegister(1, 'c')\n    qc = QuantumCircuit(k, c)\n    \n    # Iterate through each bit of 'a' to perform the addition\n    for i in range(n):\n        if (a >> i) & 1:\n            # Apply controlled-X gate if the bit is 1\n            qc.mcx([c[0]] + [k[j] for j in range(i)], k[i])\n    \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A63F29E56028A", "submission_order": 5, "result": "WA", "execution_time": "1983 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    # Create quantum registers and circuit\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    \n    # Implement controlled addition of constant a\n    # We'll add the constant only when c=1\n    for i in range(n):\n        if (a >> i) & 1:  # Check if ith bit of a is 1\n            # Add controlled-NOT gates where needed\n            qc.cx(c[0], k[i])\n            \n            # Handle carry propagation\n            for j in range(i+1, n):\n                if (a >> j) & 1:\n                    qc.ccx(c[0], k[i], k[j])\n    \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A69EBF157126A", "submission_order": 1, "result": "WA", "execution_time": "1821 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(qc: QuantumCircuit, qubits, inverse=False):\n    \"\"\"\n    リトルエンディアン版の QFT/iQFT (n^2ステップの素朴実装)。\n      - qubits[0] が最下位ビット\n      - inverse=False: 順QFT\n      - inverse=True : 逆QFT (iQFT)\n    \"\"\"\n    n = len(qubits)\n    if not inverse:\n        # --- 順QFT ---\n        for j in range(n):\n            # 1量子ビットH\n            qc.h(qubits[j])\n            # 制御位相 cp(π/2^(m-j)) for m = j+1..n-1\n            for m in range(j+1, n):\n                angle = math.pi / (2**(m-j))\n                qc.cp(angle, qubits[m], qubits[j])\n        # ビット順反転\n        for i in range(n // 2):\n            qc.swap(qubits[i], qubits[n - 1 - i])\n    else:\n        # --- 逆QFT ---\n        # ビット順反転\n        for i in range(n // 2):\n            qc.swap(qubits[i], qubits[n - 1 - i])\n        # 上から下へ\n        for j in reversed(range(n)):\n            for m in reversed(range(j+1, n)):\n                angle = - math.pi / (2**(m-j))\n                qc.cp(angle, qubits[m], qubits[j])\n            qc.h(qubits[j])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    問題:\n      整数 n, a (1 <= n <= 10, 0 <= a < 2^n) が与えられる。\n      0 <= k < 2^n, c in {0,1} の任意の組に対し、\n        |k>_n|c>_1 --> |(k + c*a) mod 2^n>_n |c>_1\n      を実装する量子回路 qc を構成せよ。\n\n    リトルエンディアン:\n      k[0] が最下位ビット (2^0)。\n    \"\"\"\n    # レジスタ k: n量子ビット, c: 1量子ビット\n    k = QuantumRegister(n, 'k')\n    c = QuantumRegister(1, 'c')\n    qc = QuantumCircuit(k, c)\n\n    # --- 1) QFT(k) ---\n    qft(qc, k, inverse=False)\n\n    # --- 2) c=1 のときだけ k に「 + a 」を加算する\n    #       具体的にはビット j=0..n-1 に単制御位相 cp( 2π a 2^j / 2^n )\n    #       リトルエンディアンなので k[j] は 2^j の重み\n    for j in range(n):\n        theta_j = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(theta_j, c[0], k[j])\n\n    # --- 3) iQFT(k) ---\n    qft(qc, k, inverse=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A69EBF157126A", "submission_order": 2, "result": "WA", "execution_time": "1953 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(qc: QuantumCircuit, qubits, inverse=False):\n    \"\"\"\n    リトルエンディアン版の QFT/iQFT (n^2ステップの素朴実装)。\n      - qubits[0] が最下位ビット\n      - inverse=False: 順QFT\n      - inverse=True : 逆QFT (iQFT)\n    \"\"\"\n    n = len(qubits)\n    if not inverse:\n        # --- 順QFT ---\n        for j in range(n):\n            # 1量子ビットH\n            qc.h(qubits[j])\n            # 制御位相 cp(π/2^(m-j)) for m = j+1..n-1\n            for m in range(j+1, n):\n                angle = math.pi / (2**(m-j))\n                qc.cp(angle, qubits[m], qubits[j])\n        # ビット順反転\n        for i in range(n // 2):\n            qc.swap(qubits[i], qubits[n - 1 - i])\n    else:\n        # --- 逆QFT ---\n        # ビット順反転\n        for i in range(n // 2):\n            qc.swap(qubits[i], qubits[n - 1 - i])\n        # 上から下へ\n        for j in reversed(range(n)):\n            for m in reversed(range(j+1, n)):\n                angle = - math.pi / (2**(m-j))\n                qc.cp(angle, qubits[m], qubits[j])\n            qc.h(qubits[j])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # --- 1) QFT(k) ---\n    qft(qc, k, inverse=False)\n\n    # --- 2) c=1 のときだけ k に「 + a 」を加算する\n    #       具体的にはビット j=0..n-1 に単制御位相 cp( 2π a 2^j / 2^n )\n    #       リトルエンディアンなので k[j] は 2^j の重み\n    for j in range(n):\n        theta_j = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(theta_j, c[0], k[j])\n\n    # --- 3) iQFT(k) ---\n    qft(qc, k, inverse=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A69EBF157126A", "submission_order": 3, "result": "RE", "execution_time": "1475 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for j in range(n):\n        theta_j = 2 * math.pi * a * (2**j) / (2**n)\n        qc.cp(theta_j, c[0], k[j])\n \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A69EBF157126A", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit.quantum_info import Statevector\nfrom qiskit.visualization import *\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nimport math \n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n \n \n# B2\ndef crot(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n \n    return qc\n \n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n \n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A69EBF157126A", "submission_order": 5, "result": "AC", "execution_time": "2058 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nimport math \n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n \n \n# B2\ndef crot(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n \n    return qc\n \n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n \n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A7334C22761EA", "submission_order": 1, "result": "AC", "execution_time": "2084 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    def f(num):\n        for i in reversed(range(num,n)):\n            qc.mcx(list(range(num,i))+[n],i)\n    for i in range(n):\n        if 2**i ^ a < a:\n            f(i)\n    \n    return qc\n\nsolve(4,3).draw()\n'''"}
{"problem": "QPC004_B3", "user": "A87A5CE9D96A3", "submission_order": 1, "result": "WA", "execution_time": "2956 ms", "memory": "158 MiB", "code": "'''python\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    Construct a quantum circuit that realises the oracle O:\n        |k⟩_n |c⟩ → |(k + c·a) mod 2^n⟩_n |c⟩   (little-endian)\n    No ancilla qubits are used, only the given n+1 qubits.\n    \"\"\"\n    # Registers (little-endian: qubit 0 = LSB)\n    k = QuantumRegister(n, \"k\")      # data register\n    c = QuantumRegister(1, \"c\")      # control qubit\n    qc = QuantumCircuit(k, c)\n\n    # --- 1.  Quantum Fourier Transform on k (little-endian, no swaps) ---\n    for i in range(n):                         # iterate LSB → MSB\n        qc.h(k[i])\n        for j in range(i + 1, n):\n            angle = pi / (2 ** (j - i))        # controlled phase R_{j-i+1}\n            qc.cp(angle, k[j], k[i])\n\n    # --- 2.  Controlled phase rotations encoding +a when c == 1 ---\n    for i in range(n):\n        # fractional part of a / 2^{i+1}\n        frac = (a % (1 << (i + 1))) / (1 << (i + 1))\n        angle = 2 * pi * frac                  # 2π * frac\n        if angle:                              # skip zero rotations\n            qc.cp(angle, c[0], k[i])           # controlled by c\n\n    # --- 3.  Inverse QFT on k (undo step 1) ---\n    for i in reversed(range(n)):\n        for j in reversed(range(i + 1, n)):\n            angle = -pi / (2 ** (j - i))\n            qc.cp(angle, k[j], k[i])\n        qc.h(k[i])\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A87A5CE9D96A3", "submission_order": 2, "result": "WA", "execution_time": "2794 ms", "memory": "160 MiB", "code": "'''python\nimport math\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef qft(qc: QuantumCircuit, q: QuantumRegister) -> None:\n    \"\"\"ビッグエンディアン実装 (SWAP あり)\"\"\"\n    n = len(q)\n    for i in reversed(range(n)):\n        qc.h(q[i])\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), q[j], q[i])\n    for i in range(n // 2):                      # 反転してリトルエンディアンに戻す\n        qc.swap(q[i], q[n - i - 1])\n\n\ndef iqft(qc: QuantumCircuit, q: QuantumRegister) -> None:\n    \"\"\"qft の逆演算\"\"\"\n    n = len(q)\n    for i in reversed(range(n // 2)):            # SWAP を先に戻す\n        qc.swap(q[i], q[n - i - 1])\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-pi / 2 ** (i - j), q[j], q[i])\n        qc.h(q[i])\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    Oracle O:\n        |k⟩_n |c⟩ → |(k + c·a) mod 2^n⟩_n |c⟩\n    * 整数はリトルエンディアン (qubit 0 = LSB)\n    * 追加の量子ビットは使用しない\n    \"\"\"\n    k = QuantumRegister(n, \"k\")      # データレジスタ\n    c = QuantumRegister(1, \"c\")      # 制御ビット\n    qc = QuantumCircuit(k, c)\n\n    # 1. QFT\n    qft(qc, k)                       # ここでレジスタは再びリトルエンディアン順\n\n    # 2. +a を位相に刻む（c==1 のときのみ）\n    #    各フーリエ量子ビット i (LSB から) に角度 2π·a / 2^{i+1}\n    for i in range(n):\n        angle = (2 * pi * a) / (1 << (i + 1))\n        # 角度が 0 (a が 2^{i+1} の倍数) ならスキップ\n        if angle % (2 * pi):\n            qc.cp(angle, c[0], k[i])\n\n    # 3. 逆 QFT\n    iqft(qc, k)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A87A5CE9D96A3", "submission_order": 3, "result": "AC", "execution_time": "2737 ms", "memory": "161 MiB", "code": "'''python\nimport math\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef qft_le(qc: QuantumCircuit, q: QuantumRegister) -> None:\n    \"\"\"little-endian QFT with final SWAP (式(2) を実現)\"\"\"\n    n = len(q)\n    for i in reversed(range(n)):\n        qc.h(q[i])\n        for j in reversed(range(i)):\n            qc.cp(pi / 2**(i - j), q[j], q[i])\n    for i in range(n // 2):\n        qc.swap(q[i], q[n - i - 1])\n\n\ndef iqft_le(qc: QuantumCircuit, q: QuantumRegister) -> None:\n    n = len(q)\n    for i in reversed(range(n // 2)):\n        qc.swap(q[i], q[n - i - 1])\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-pi / 2**(i - j), q[j], q[i])\n        qc.h(q[i])\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"\n    |k⟩_n|c⟩ → |(k + c·a) mod 2^n⟩_n|c⟩   (little-endian, ancilla-free)\n    \"\"\"\n    k = QuantumRegister(n, \"k\")       # データ\n    c = QuantumRegister(1, \"c\")       # 制御\n    qc = QuantumCircuit(k, c)\n\n    # 1) QFT\n    qft_le(qc, k)\n\n    # 2) controlled R_i(a)  — 角度は 2π a / 2^{n-i} !\n    for i in range(n):\n        angle = 2 * pi * a / (1 << (n - i))\n        if angle % (2 * pi):\n            qc.cp(angle, c[0], k[i])  # 控えめに skip(0∘)\n\n    # 3) inverse QFT\n    iqft_le(qc, k)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A905992469825", "submission_order": 1, "result": "AC", "execution_time": "2291 ms", "memory": "163 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft_n =qft(n)\n    \n    qc.compose(qft_n,k,inplace=True)\n    \n    for i in range(n):\n        theta = 2 * pi * a * 2**i / 2**n\n        qc.cp(theta,n, i)\n    \n    qc.compose(qft_n.inverse(),k,inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A949A12AF4E8B", "submission_order": 1, "result": "RE", "execution_time": "2061 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    # QFT\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    # B2\n    for i in range(n):\n        qc.cp(2 * math.pi * a * 2 ** (i - n), c[0], k[i])\n\n    # IQFT\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    for i in reversed(range(n)):\n        for j in reversed(range(i)):\n            qc.cp(-math.pi / 2 ** (i - j), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A949A12AF4E8B", "submission_order": 2, "result": "WA", "execution_time": "1729 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    # QFT\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    # B2\n    for i in range(n):\n        qc.cp(2 * math.pi * a * 2 ** (i - n), c[0], k[i])\n\n    # IQFT\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    for i in reversed(range(n)):\n        for j in reversed(range(i)):\n            qc.cp(-math.pi / 2 ** (i - j), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A949A12AF4E8B", "submission_order": 3, "result": "WA", "execution_time": "1973 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    # QFT\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    # B2\n    for i in range(n):\n        qc.cp(2 * math.pi * a * 2 ** (i - n), c[0], k[i])\n\n    # IQFT\n    for i in reversed(range(n)):\n        for j in reversed(range(i)):\n            qc.cp(-math.pi / 2 ** (i - j), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A949A12AF4E8B", "submission_order": 4, "result": "AC", "execution_time": "2195 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    # QFT\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    # B2\n    for i in range(n):\n        qc.cp(2 * math.pi * a * 2 ** (i - n), c[0], k[i])\n\n    # IQFT\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-math.pi / 2 ** (i - j), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "A9681F87D02A7", "submission_order": 1, "result": "AC", "execution_time": "2228 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            theta = math.pi / 2 ** (i - j)\n            qc.cp(theta, j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.compose(qft(n), inplace=True)\n\n    for i in range(n):\n        theta = 2 * math.pi * a * (2 ** i)  / (2 ** n)\n        qc.cp(theta, k[i], c)\n\n    qc.compose(qft(n).inverse(), inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ABA0FBCE63148", "submission_order": 1, "result": "AC", "execution_time": "2060 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for _ in range(a):\n        for i in range(n-1,-1,-1):\n            qc.mcx([n]+list(range(i)),i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ABD8320A7C0BA", "submission_order": 1, "result": "RE", "execution_time": "1602 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ch(n, i)\n        for j in range(i+1, n):\n            qc.mcp(2 * np.pi / 2 ** (j), [j, n], i)\n    for i in range(n // 2):\n        qc.cswap(n, i, (n - i - 1))\n\n    for i in range(n):\n        angle = (2 * np.pi * ((a >> i) & 1)) / 2 ** (i + 1)\n        if (angle != 0):\n            qc.cp(n, angle, i)\n    \n    for i in range(n // 2):\n        qc.cswap(n, i, (n - i - 1))\n    \n    for i in reversed(range(n)):\n        for j in reversed(range(i + 1, n)):\n            qc.mcp(-2 * np.pi / 2 ** (j), [j, n], i)\n        qc.ch(n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ABD8320A7C0BA", "submission_order": 2, "result": "WA", "execution_time": "1768 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ch(n, i)\n        for j in range(i+1, n):\n            qc.mcp(2 * np.pi / 2 ** (j), [j, n], i)\n    for i in range(n // 2):\n        qc.cswap(n, i, (n - i - 1))\n\n    for i in range(n):\n        angle = (2 * np.pi * ((a >> i) & 1)) / 2 ** (i + 1)\n        if (angle != 0):\n            qc.cp(angle, n, i)\n    \n    for i in range(n // 2):\n        qc.cswap(n, i, (n - i - 1))\n    \n    for i in reversed(range(n)):\n        for j in reversed(range(i + 1, n)):\n            qc.mcp(-2 * np.pi / 2 ** (j), [j, n], i)\n        qc.ch(n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ABD8320A7C0BA", "submission_order": 3, "result": "WA", "execution_time": "1649 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    for i in range(n):\n        qc.ch(n, i)\n        for j in range(i+1, n):\n            qc.mcp(2 * np.pi / 2 ** (j), [j, n], i)\n    for i in range(n // 2):\n        qc.cswap(n, i, (n - i - 1))\n\n    for i in range(n):\n        angle = (2 * np.pi * ((a >> i) & 1)) / 2 ** (i + 1)\n        qc.cp(angle, n, i)\n    \n    for i in range(n // 2):\n        qc.cswap(n, i, (n - i - 1))\n    \n    for i in reversed(range(n)):\n        for j in reversed(range(i + 1, n)):\n            qc.mcp(-2 * np.pi / 2 ** (j), [j, n], i)\n        qc.ch(n, i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ABD8320A7C0BA", "submission_order": 4, "result": "AC", "execution_time": "1785 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    QFT(qc, list(range(n)))\n\n    for i in range(n):\n        theta = 2 * math.pi * a * (2 ** i) / (2 ** n)\n        qc.cp(theta, n, i)\n\n    QFT(qc, list(range(n)), inversed = True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AC2F39289CA42", "submission_order": 1, "result": "WA", "execution_time": "1919 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n)  # Register for k\n    c = QuantumRegister(1)   # Register for c\n    qc = QuantumCircuit(k, c)\n    \n    # Convert a to its binary representation\n    a_bin = [int(x) for x in format(a, f'0{n}b')[::-1]]  # Little-endian binary representation of a\n    \n    # Apply the controlled addition of a if c is 1\n    for i in range(n):\n        if a_bin[i] == 1:\n            # Use a Toffoli gate to control the addition\n            # We need to add a to k if c is 1\n            # This means we need to add a to k[i] controlled by c[0]\n            # We will use a series of CNOT and Toffoli gates\n            \n            # First, we need to create a carry bit\n            if i == 0:\n                # For the least significant bit, we can directly use CNOT\n                qc.cx(c[0], k[i])\n            else:\n                # For higher bits, we need to use Toffoli gates to handle carry\n                # Create a carry bit from the previous bit\n                qc.ccx(c[0], k[i-1], k[i])  # Toffoli gate\n                qc.cx(c[0], k[i])  # CNOT gate for the current bit\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AC4E92525913A", "submission_order": 1, "result": "WA", "execution_time": "1916 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for j in range(a):\n        for i in range(n):\n            qc.x(i)\n        qc.x(0)\n        for i in range(n - 1):\n            qc.mcx(list(range(0, i + 1)) + [n], i + 1)\n        for i in range(n):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AC4E92525913A", "submission_order": 2, "result": "AC", "execution_time": "3000 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for j in range(a):\n        for i in range(n):\n            qc.x(i)\n        qc.cx(n, 0)\n        for i in range(n - 1):\n            qc.mcx(list(range(0, i + 1)) + [n], i + 1)\n        for i in range(n):\n            qc.x(i)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AC81DF0F2E8D7", "submission_order": 1, "result": "WA", "execution_time": "1913 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    import math    \n    if False:\n    \tisv = Statevector([1 if i == (1+8) else 0 for i in range(16)])\n    \tprint(isv)\n    \tqc.prepare_state(isv)\n    \n    # QFT\n    for i in range(n)[::-1]:\n    \tqc.h(i)\n    \tfor j in range(i)[::-1]:\n    \t    t = 2 * math.pi / (2 ** (i-j+1))\n    \t    qc.cp(t,j,i)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    \n    # op\n    \n    for i in range(n):\n    \tt = 2 * math.pi * a * (2 ** i) / (2 ** n)\n    \tqc.cp(t,n,i)\n    \n    # IQFT\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    \n    for i in range(n):\n    \tfor j in range(i):\n    \t    t = 2 * math.pi / (2 ** (i-j+1))\n    \t    qc.cp(t,j,i)\n    \tqc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AC81DF0F2E8D7", "submission_order": 2, "result": "RE", "execution_time": "1631 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    import math    \n    if False:\n    \tisv = Statevector([1 if i == (3+8) else 0 for i in range(2**(n+1))])\n    \tprint(isv)\n    \tqc.prepare_state(isv)\n    \n    # QFT\n    for i in range(n)[::-1]:\n    \tqc.h(i)\n    \tfor j in range(i)[::-1]:\n    \t    t = 2 * math.pi / (2 ** (i-j+1))\n    \t    qc.cp(t,j,i)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    \n    # op\n    \n    for i in range(n):\n    \tt = 2 * math.pi * a * (2 ** i) / (2 ** n)\n    \tqc.cp(t,n,i)\n    \n    # IQFT\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    \n    for i in range(n):\n    \tfor j in range(i):\n    \t    t = - 2 * math.pi / (2 ** (i-j+1))\n    \t    qc.cp(t,j,i)\n    \tqc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AC81DF0F2E8D7", "submission_order": 3, "result": "AC", "execution_time": "2053 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    \n    import math    \n    if False:\n    \tisv = Statevector([1 if i == (3+8) else 0 for i in range(2**(n+1))])\n    \tprint(isv)\n    \tqc.prepare_state(isv)\n    \n    # QFT\n    for i in range(n)[::-1]:\n    \tqc.h(i)\n    \tfor j in range(i)[::-1]:\n    \t    t = 2 * math.pi / (2 ** (i-j+1))\n    \t    qc.cp(t,j,i)\n\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    \n    # op\n    \n    for i in range(n):\n    \tt = 2 * math.pi * a * (2 ** i) / (2 ** n)\n    \tqc.cp(t,n,i)\n    \n    # IQFT\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    \n    for i in range(n):\n    \tfor j in range(i):\n    \t    t = - 2 * math.pi / (2 ** (i-j+1))\n    \t    qc.cp(t,j,i)\n    \tqc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA3B5C253E19", "submission_order": 1, "result": "AC", "execution_time": "2172 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n : int, a : int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n\n    for k in range(n):\n        if(a%2 == 1):\n            for i in range(n-1,k-1,-1):\n                if(i == k):\n                    qc.cx(n,i)\n                else:\n                    qc.mcx(list(range(k,i,1)) + [n],i)\n        a = int(a/2)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA91A9AB03F8", "submission_order": 1, "result": "WA", "execution_time": "2108 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n    qc.inverse()\n    qc.repeat(a)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA91A9AB03F8", "submission_order": 2, "result": "WA", "execution_time": "1910 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.cx(n, 0)\n    for i in range(1, n):\n        qc.mcx(list(range(i))+[n], i)\n    qc.inverse()\n    qc.repeat(a)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA91A9AB03F8", "submission_order": 3, "result": "WA", "execution_time": "2492 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.cx(n, 0)\n    for i in range(1, n):\n        qc.mcx(list(range(i))+[n], i)\n    qc.repeat(2**n-a)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA91A9AB03F8", "submission_order": 4, "result": "WA", "execution_time": "1900 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if((a >> i)&1):\n            qc.cx(n, i)\n            for j in range(i+1, n):\n                qc.mcx([c] + list(range(i, j)), j)\n    qc.inverse()\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA91A9AB03F8", "submission_order": 5, "result": "WA", "execution_time": "1948 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if((a >> i)&1):\n            qc.cx(n, i)\n            for j in range(i+1, n):\n                qc.mcx([n] + list(range(i, j)), j)\n    qc.inverse()\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA91A9AB03F8", "submission_order": 6, "result": "WA", "execution_time": "2558 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if((a >> i)&1):\n            for j in range(n):\n                l =[c]\n                for k in range(j):\n                    l.append((k + i) % n)\n                qc.mcx(l, (j+i)%n)\n    qc.inverse()\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA91A9AB03F8", "submission_order": 7, "result": "WA", "execution_time": "1848 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if((a >> i)&1):\n            for j in range(n):\n                l =[n]\n                for k in range(j):\n                    l.append((k + i) % n)\n                qc.mcx(l, (j+i)%n)\n    qc.inverse()\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACA91A9AB03F8", "submission_order": 8, "result": "WA", "execution_time": "1903 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        if((a >> i)&1):\n            for j in range(i, n):\n                qc.mcx([n] + list(range(i, j)), j)\n    qc.inverse()\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 1, "result": "RE", "execution_time": "1778 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        for i in range(n):\n            theta = (2 * math.pi * a / 2**m) * 2**j\n            qc.mcp(theta, [x[i],c], y[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 2, "result": "RE", "execution_time": "1810 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        for i in range(n):\n            theta = (math.pi * a / 2**n) * 2**j\n            qc.cp(theta, c, k[i])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 3, "result": "RE", "execution_time": "1677 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        theta = (math.pi * (a & 2**j) / 2**n) * 2**j\n        qc.cp(theta, c, k[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 4, "result": "RE", "execution_time": "1710 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        theta = (2 * math.pi * (a & 2**j) / 2**n) * 2**j\n        qc.cp(theta, c[0], k[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 5, "result": "RE", "execution_time": "1508 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    # for j in range(n):\n    #     theta = (2 * math.pi * (a & 2**j) / 2**n) * 2**j\n    #     qc.cp(theta, c[0], k[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 6, "result": "RE", "execution_time": "1656 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    # qc.compose(qft_n, k, inplace=True)\n \n    # for j in range(n):\n    #     theta = (2 * math.pi * (a & 2**j) / 2**n) * 2**j\n    #     qc.cp(theta, c[0], k[j])\n \n    # qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 7, "result": "WA", "execution_time": "1585 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    # qft_n = qft(n)\n \n    # qc.compose(qft_n, k, inplace=True)\n \n    # for j in range(n):\n    #     theta = (2 * math.pi * (a & 2**j) / 2**n) * 2**j\n    #     qc.cp(theta, c[0], k[j])\n \n    # qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 8, "result": "WA", "execution_time": "1635 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    # for j in range(n):\n    #     theta = (2 * math.pi * (a & 2**j) / 2**n) * 2**j\n    #     qc.cp(theta, c[0], k[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 9, "result": "WA", "execution_time": "1705 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        theta = (2 * math.pi * (a & 2**j) / 2**n) * 2**j\n        qc.cp(theta, c[0], k[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 10, "result": "WA", "execution_time": "1997 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        theta = (2 * math.pi * (a & 2**j) / 2**n) * 2**j\n        qc.cp(theta, c[0], k[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 11, "result": "WA", "execution_time": "1995 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        if (a & (1 << j)):  # Check if j-th bit of a is 1\n            theta = 2 * math.pi * 2**j / 2**n\n            qc.cp(theta, c[0], k[n-1-j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 12, "result": "WA", "execution_time": "1630 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        if (a & (1 << j)):  # Check if j-th bit of a is 1\n            theta = 2 * math.pi * 2**j / 2**n\n            qc.cp(theta, c[0], k[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 13, "result": "WA", "execution_time": "1810 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        theta = 2 * math.pi * a * 2**j / 2**n\n        qc.cp(theta, c[0], k[n-1-j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ACD0ABF166BCF", "submission_order": 14, "result": "AC", "execution_time": "1979 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qft_n = qft(n)\n \n    qc.compose(qft_n, k, inplace=True)\n \n    for j in range(n):\n        theta = 2 * math.pi * a * 2**j / 2**n\n        qc.cp(theta, c[0], k[j])\n \n    qc.compose(qft_n.inverse(), k, inplace=True)\n\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 1, "result": "RE", "execution_time": "2187 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.crz(2*math.pi/2**(j+1), j, i)\n        \n    for i in range(n//2):\n        qc.swap(i, n-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 2, "result": "RE", "execution_time": "1844 ms", "memory": "158 MiB", "code": "'''python\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.crz(2*math.pi/2**(j+1), j, i)\n        \n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 3, "result": "RE", "execution_time": "2345 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.crz(2*math.pi/2**(j+1), j, i)\n        qc.barrier()\n        \n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    #qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    #qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n\nsolve(3,1).draw(\"mpl\")\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 4, "result": "WA", "execution_time": "2377 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.crz(2*math.pi/2**(j+1), j, i)\n        qc.barrier()\n        \n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 5, "result": "WA", "execution_time": "2204 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.crz(2*math.pi/2**(j+1), j, i)\n        qc.barrier()\n        \n    # for i in range(n//2):\n    #     qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 6, "result": "WA", "execution_time": "2114 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(2*math.pi/2**(j+1), j, i)\n        qc.barrier()\n        \n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 7, "result": "WA", "execution_time": "1876 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(2*math.pi/2**(j+1), j, i)\n        qc.barrier()\n        \n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 8, "result": "WA", "execution_time": "2116 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.cp(2*math.pi/2**(j+1), j, i)\n        qc.barrier()\n        \n    # for i in range(n//2):\n    #     qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 9, "result": "WA", "execution_time": "2573 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(2*math.pi/2**(n-j), j, i)\n        qc.barrier()\n        \n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AD1F256D695CD", "submission_order": 10, "result": "AC", "execution_time": "2233 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(2*math.pi/2**(i-j+1), j, i)\n        qc.barrier()\n        \n    for i in range(n//2):\n        qc.swap(i, n-1-i)\n        \n    return qc\n        \ndef crot(n, a):\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    for i in range(n):\n        qc.cp(2*math.pi*a*2**i/2**n, c, i)\n\n    return qc\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ADB24C647A3A2", "submission_order": 1, "result": "WA", "execution_time": "1991 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n\n    for q in range(n):\n        current_a_bit = a % 2\n        a //=2\n        if current_a_bit == 1:\n            for i in range(q+1, n):\n                qc.mcx([c[0], q] + list(range(i+1, n)), i)\n            qc.x(q)\n        else:\n            assert current_a_bit == 0\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ADB24C647A3A2", "submission_order": 2, "result": "WA", "execution_time": "1931 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n\n    for q in range(n):\n        current_a_bit = a % 2\n        a //=2\n        if current_a_bit == 1:\n            for i in range(q+1, n):\n                qc.mcx([c[0]] + list(range(q, i)), i)\n            qc.x(q)\n        else:\n            assert current_a_bit == 0\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ADB24C647A3A2", "submission_order": 3, "result": "AC", "execution_time": "2323 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef crot(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), qubits=k, inplace=True)\n    qc.compose(crot(n, a), qubits=[*k, *c], inplace=True)\n    qc.compose(qft(n).inverse(), qubits=k, inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 1, "result": "WA", "execution_time": "1785 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tvis = [False] * 2**n\n\tfor start in range(2**n):\n\t\tif vis[start]:\n\t\t\tcontinue\n\t\tvis[start] = True\n\t\tx = start\n\t\twhile not vis[(x - a) % 2**n]:\n\t\t\ty = (x - a) % 2**n\n\t\t\tvis[y] = True\n\t\t\tto_flip = []\n\t\t\tto_control = []\n\t\t\tto_zero_control = []\n\t\t\tfor i in range(n):\n\t\t\t\tif (x ^ y) >> i & 1:\n\t\t\t\t\tto_flip.append(i)\n\t\t\t\telse:\n\t\t\t\t\tto_control.append(i)\n\t\t\t\t\tif ~x >> i & 1:\n\t\t\t\t\t\tto_zero_control.append(i)\n\t\t\tfor i in to_zero_control:\n\t\t\t\tqc.x(i)\n\t\t\tfor i in to_flip:\n\t\t\t\tif to_control:\n\t\t\t\t\tqc.mcx(to_control, i)\n\t\t\t\telse:\n\t\t\t\t\tqc.x(i)\n\t\t\tfor i in to_zero_control:\n\t\t\t\tqc.x(i)\n\t\t\tx = y\n\treturn qc\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 2, "result": "WA", "execution_time": "2342 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tfor cycle in sorted(cycles, key = lambda c: len(c)):\n\t\tdef recurse(l, r):\n\t\t\tif r - l <= 1:\n\t\t\t\treturn\n\t\t\tm = l + r >> 1\n\t\t\trecurse(l, m), recurse(m, r)\n\t\t\tx, y = cycle[l], cycle[m]\n\t\t\tdef apply_swap(i):\n\t\t\t\tfor j in range(n):\n\t\t\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\t\t\tqc.x(j)\n\t\t\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\t\t\tfor j in range(n):\n\t\t\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\t\t\tqc.x(j)\n\t\t\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\t\t\tcut = len(diff) >> 1\n\t\t\tfor i in range(cut - 1):\n\t\t\t\tapply_swap(diff[i])\n\t\t\tfor i in range(cut + 1, len(diff)):\n\t\t\t\tapply_swap(diff[i])\n\t\t\tapply_swap(diff[cut])\n\t\t\tfor i in range(cut - 1):\n\t\t\t\tapply_swap(diff[i])\n\t\t\tfor i in range(cut + 1, len(diff)):\n\t\t\t\tapply_swap(diff[i])\n\t\trecurse(0, len(cycle))\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [(j << n) + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\tprint(f\"{perm = }\")\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 3, "result": "RE", "execution_time": "1613 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\ndef apply_stateswap(qc, x, y):\n\tn = qc.num_qubits\n\tassert x != y\n\tassert 0 <= min(x, y) and max(x, y) < 2**n\n\tdef apply_bitswap(i):\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\tcut = len(diff) / 2\n\tfor i in range(cut - 1):\n\t\tapply_bitswap(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitswap(diff[i])\n\tapply_bitswap(diff[cut])\n\tfor i in range(cut - 1):\n\t\tapply_bitswap(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitswap(diff[i])\n\treturn qc\n\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tfor cycle in sorted(cycles, key = lambda c: len(c)):\n\t\tdef recurse(l, r):\n\t\t\tif r - l <= 1:\n\t\t\t\treturn\n\t\t\tm = l + r >> 1\n\t\t\trecurse(l, m), recurse(m, r)\n\t\t\tapply_stateswap(qc, cycle[l], cycle[m])\n\t\trecurse(0, len(cycle))\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [2**n * j + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 4, "result": "WA", "execution_time": "1974 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\ndef apply_stateswap(qc, x, y):\n\tn = qc.num_qubits\n\tassert x != y\n\tassert 0 <= min(x, y) and max(x, y) < 2**n\n\tdef apply_bitswap(i):\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\tcut = len(diff) // 2\n\tfor i in range(cut - 1):\n\t\tapply_bitswap(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitswap(diff[i])\n\tapply_bitswap(diff[cut])\n\tfor i in range(cut - 1):\n\t\tapply_bitswap(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitswap(diff[i])\n\treturn qc\n\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tfor cycle in sorted(cycles, key = lambda c: len(c)):\n\t\tdef recurse(l, r):\n\t\t\tif r - l <= 1:\n\t\t\t\treturn\n\t\t\tm = l + r >> 1\n\t\t\trecurse(l, m), recurse(m, r)\n\t\t\tapply_stateswap(qc, cycle[l], cycle[m])\n\t\trecurse(0, len(cycle))\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [2**n * j + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 5, "result": "WA", "execution_time": "2505 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\n# Adds about 3n circuit depth\ndef apply_stateswap(qc, x, y):\n\tn = qc.num_qubits\n\tassert x != y\n\tassert 0 <= min(x, y) and max(x, y) < 2**n\n\tdef apply_bitflip(i):\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\tcut = len(diff) // 2\n\tfor i in range(cut):\n\t\tapply_bitflip(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitflip(diff[i])\n\tapply_bitflip(diff[cut])\n\tfor i in range(cut):\n\t\tapply_bitflip(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitflip(diff[i])\n\treturn qc\n\n# Adds about 3 * n * 2**n circuit depth\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tops = 2\n\tfor cycle in cycles:\n\t\tfor i in reversed(range(len(cycle) - 1)):\n\t\t\tapply_stateswap(qc, cycle[i], cycle[i + 1])\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [2**n * j + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 6, "result": "WA", "execution_time": "2070 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\n# Adds about 3n circuit depth\ndef apply_stateswap(qc, x, y):\n\tn = qc.num_qubits\n\tassert x != y\n\tassert 0 <= min(x, y) and max(x, y) < 2**n\n\tdef apply_bitflip(i):\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\tcut = len(diff) // 2\n\tfor i in range(cut):\n\t\tapply_bitflip(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitflip(diff[i])\n\tapply_bitflip(diff[cut])\n\tfor i in range(cut):\n\t\tapply_bitflip(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitflip(diff[i])\n\treturn qc\n\n# Adds about 3 * n * 2**n circuit depth\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tops = 2\n\tfor cycle in cycles:\n\t\tfor i in range(len(cycle) - 1):\n\t\t\tapply_stateswap(qc, cycle[i], cycle[i + 1])\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [2**n * j + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 7, "result": "TLE", "execution_time": "3000 ms", "memory": "177 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\n# Adds about 3n circuit depth\ndef apply_stateswap(qc, x, y):\n\tn = qc.num_qubits\n\tassert 0 <= min(x, y) and max(x, y) < 2**n\n\tif x == y:\n\t\treturn qc\n\tdef apply_bitflip(i):\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\tcut = len(diff) // 2\n\tfor i in range(cut):\n\t\tapply_bitflip(diff[i])\n\tfor i in reversed(range(cut + 1, len(diff))):\n\t\tapply_bitflip(diff[i])\n\tapply_bitflip(diff[cut])\n\tfor i in reversed(range(cut)):\n\t\tapply_bitflip(diff[i])\n\tfor i in range(cut + 1, len(diff)):\n\t\tapply_bitflip(diff[i])\n\treturn qc\n\n# Adds about 3 * n * 2**n circuit depth\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tops = 2\n\tfor cycle in cycles:\n\t\tfor i in reversed(range(len(cycle) - 1)):\n\t\t\tapply_stateswap(qc, cycle[i], cycle[i + 1])\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [2**n * j + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 8, "result": "RE", "execution_time": "2668 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\n# Adds up to 6n circuit depth\ndef apply_stateswap(qc, x, y):\n\tn = qc.num_qubits\n\tassert 0 <= min(x, y) and max(x, y) < 2**n\n\tif x == y:\n\t\treturn qc\n\tdef apply_bitflip(i):\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\tfor i in diff:\n\t\tapply_bitflip(i)\n\tfor i in reversed(range(diff[:-1])):\n\t\tapply_bitflip(diff[i])\n\treturn qc\n\n# Adds up to 4 * n * 2**n circuit depth\n# Requires apply_stateswap\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tops = 2\n\tfor cycle in cycles:\n\t\tfor i in reversed(range(len(cycle) - 1)):\n\t\t\tapply_stateswap(qc, cycle[i], cycle[i + 1])\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [2**n * j + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 9, "result": "TLE", "execution_time": "3000 ms", "memory": "177 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\n# Adds up to 6n circuit depth\ndef apply_stateswap(qc, x, y):\n\tn = qc.num_qubits\n\tassert 0 <= min(x, y) and max(x, y) < 2**n\n\tif x == y:\n\t\treturn qc\n\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\tfor i in diff + list(reversed(diff[:-1])):\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\tfor j in range(n):\n\t\t\tif j < i and ~x >> j & 1 or j > i and ~y >> j & 1:\n\t\t\t\tqc.x(j)\n\treturn qc\n\n# Adds up to 4 * n * 2**n circuit depth\n# Requires apply_stateswap\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tops = 2\n\tfor cycle in cycles:\n\t\tfor i in reversed(range(len(cycle) - 1)):\n\t\t\tapply_stateswap(qc, cycle[i], cycle[i + 1])\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [2**n * j + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "ADF2C94479F92", "submission_order": 10, "result": "TLE", "execution_time": "3000 ms", "memory": "176 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom numpy import pi, sqrt, acos\n\n# Adds up to 4 * n circuit depth\ndef apply_stateswap(qc, x, y):\n\tn = qc.num_qubits\n\tassert 0 <= min(x, y) and max(x, y) < 2**n\n\tif x == y:\n\t\treturn qc\n\tdiff = [i for i in range(n) if (x ^ y) >> i & 1]\n\tlast_mask = 0\n\tfor i in diff + list(reversed(diff[:-1])):\n\t\tcur_mask = ~x & (2**i - 1) | ~y & (2**n - 2**(i + 1))\n\t\tfor j in range(n):\n\t\t\tif (last_mask ^ cur_mask) >> j & 1:\n\t\t\t\tqc.x(j)\n\t\tqc.mcx(list(j for j in range(n) if i != j), i)\n\t\tlast_mask = cur_mask\n\tfor j in range(n):\n\t\tif last_mask >> j & 1:\n\t\t\tqc.x(j)\n\treturn qc\n\n# Adds up to 4 * n * 2**n circuit depth\n# Requires apply_stateswap\ndef apply_permutation(qc, p, option = \"cycle\"):\n\tassert option in [\"cycle\", \"list\"]\n\tn = qc.num_qubits\n\tcycles = []\n\tif option == \"cycle\":\n\t\tcycles = p[:]\n\telif option == \"list\":\n\t\tassert sorted(p) == list(range(len(p)))\n\t\tvis = [False] * len(p)\n\t\tfor x in range(len(p)):\n\t\t\tif vis[x]:\n\t\t\t\tcontinue\n\t\t\tcycle = []\n\t\t\twhile not vis[x]:\n\t\t\t\tvis[x] = True\n\t\t\t\tcycle.append(x)\n\t\t\t\tx = p[x]\n\t\t\tcycles.append(cycle)\n\telse:\n\t\tassert False\n\tops = 2\n\tfor cycle in cycles:\n\t\tfor i in reversed(range(len(cycle) - 1)):\n\t\t\tapply_stateswap(qc, cycle[i], cycle[i + 1])\n\treturn qc\n\ndef solve(n, a) -> QuantumCircuit:\n\tk, c = QuantumRegister(n), QuantumRegister(1)\n\tqc = QuantumCircuit(k, c)\n\tperm = [2**n * j + (i + a * j) % 2**n for j in range(2) for i in range(2**n)]\n\treturn apply_permutation(qc, perm, option = \"list\")\n'''"}
{"problem": "QPC004_B3", "user": "AE88B5E72488F", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, QFT\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef addition(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.append(QFT(n), range(n))\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)), [i])\n    qc.append(QFT(n).inverse(), range(n))\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # qc.x(n)\n    \n    qc.append(QFT(n).control(1), [n, *range(n)])\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)).control(1), [n, i])\n    qc.append(QFT(n,inverse=True).control(1), [n, *range(n)])\n \n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AE88B5E72488F", "submission_order": 2, "result": "AC", "execution_time": "2920 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(CU1Gate(pi/2**(j-i)), [j, i])\n    return qc\n\ndef addition(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(QFT(n), range(n), inplace=True)\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)), [i])\n    qc.compose(QFT(n).inverse(), range(n), inplace=True)\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # qc.x(n)\n    \n    qc.append(QFT(n).control(1), [n, *range(n)])\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)).control(1), [n, i])\n    qc.append(QFT(n).inverse().control(1), [n, *range(n)])\n \n    return qc.decompose(reps=2)\n'''"}
{"problem": "QPC004_B3", "user": "AE98211E8CDAD", "submission_order": 1, "result": "RE", "execution_time": "1771 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(qc: QuantumCircuit, qubits):\n    n = len(qubits)\n    for j in range(n):\n        qc.h(qubits[j])\n        for k in range(j+1, n):\n            qc.cp(math.pi/2**(k - j), qubits[k], qubits[j])\n            \ndef iqft(qc: QuantumCircuit, qubits):\n    n = len(qubits)\n    for j in reversed(range(n)):\n        for k in reversed(range(j+1, n)):\n            qc.cp(-math.pi/2**(k - j), qubits[k], qubits[j])\n        qc.h(qubits[j])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft(qc, k)\n    \n    for j in range(n):\n        angle = 2 * math.pi * a / (2 ** (j + 1))\n        qc.cp(angle, c[0], k[j])\n    \n    iqft(qc, k)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AE98211E8CDAD", "submission_order": 2, "result": "WA", "execution_time": "2077 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(qc: QuantumCircuit, qubits):\n    n = len(qubits)\n    for j in range(n):\n        qc.h(qubits[j])\n        for k in range(j+1, n):\n            qc.cp(math.pi/2**(k - j), qubits[k], qubits[j])\n            \ndef iqft(qc: QuantumCircuit, qubits):\n    n = len(qubits)\n    for j in reversed(range(n)):\n        for k in reversed(range(j+1, n)):\n            qc.cp(-math.pi/2**(k - j), qubits[k], qubits[j])\n        qc.h(qubits[j])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft(qc, k)\n    \n    for j in range(n):\n        angle = 2 * math.pi * a / (2 ** (j + 1))\n        qc.cp(angle, c[0], k[j])\n    \n    iqft(qc, k)\n\n    return qc\n'''"}
{"problem": "QPC004_B3", "user": "AE98211E8CDAD", "submission_order": 3, "result": "WA", "execution_time": "1722 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef qft(qc: QuantumCircuit, qubits):\n    n = len(qubits)\n    for j in range(n):\n        qc.h(qubits[j])\n        for k in range(j+1, n):\n            qc.cp(math.pi/2**(k - j), qubits[k], qubits[j])\n            \ndef iqft(qc: QuantumCircuit, qubits):\n    n = len(qubits)\n    for j in reversed(range(n)):\n        for k in range(n-1, j, -1):\n            qc.cp(-math.pi/2**(k - j), qubits[k], qubits[j])\n        qc.h(qubits[j])\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft(qc, k)\n    \n    for j in range(n):\n        angle = 2 * math.pi * a * (2 ** j) / (2 ** n)\n        qc.cp(angle, c[0], k[j])\n    \n    iqft(qc, k)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A387379FDE520", "submission_order": 1, "result": "AC", "execution_time": "2143 ms", "memory": "161 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit\n \n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n \n \n# B2\ndef crot(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n \n    return qc\n \n \n# B3\ndef cadd(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n \n    qc.compose(qft(n), qubits=range(n), inplace=True)\n    qc.compose(crot(n, a), qubits=range(n + 1), inplace=True)\n    qc.compose(qft(n).inverse(), qubits=range(n), inplace=True)\n \n    return qc\n \n \ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n \n    # when k_{n-1} = 1\n    qc.compose(cadd(n, 2 ** (n + 1) - t), qubits=range(n + 1), inplace=True)\n \n    # when k_{n-1} = 0\n    qc.x(n)\n    qc.compose(cadd(n, -s), qubits=range(n + 1), inplace=True)\n    qc.x(n)\n \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A3965CFA5FFA8", "submission_order": 1, "result": "AC", "execution_time": "2318 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\nimport math\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            theta = math.pi / 2 ** (i - j)\n            qc.cp(theta, j, i)\n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n    return qc\n\n\ndef add_constant_controlled(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qc.compose(qft(n), inplace=True)\n    for i in range(n):\n        theta = 2 * math.pi * a * (2 ** i)  / (2 ** n)\n        qc.cp(theta, k[i], c)\n    qc.compose(qft(n).inverse(), inplace=True)\n    return qc\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.x(n)\n    qc.compose(add_constant_controlled(n, (2**n - s)), qubits=range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(add_constant_controlled(n, (2**(n+1)-t)), qubits=range(n + 1), inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A75C492DA58D2", "submission_order": 1, "result": "RE", "execution_time": "1806 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    for i in range(n): qc.cx(i, n)\n    for i in range(n):\n        qc.ccx(i, n, n + 1)\n        qc.cx(i, n + 1)\n        qc.ccx(i, n, n + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A75C492DA58D2", "submission_order": 2, "result": "RE", "execution_time": "1568 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    qc.cx(range(n), n)\n    qc.ccx(range(n), n, n + 1)\n    qc.cx(range(n), n + 1)\n    qc.ccx(range(n), n, n + 1)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A7CC3BCDF0EE9", "submission_order": 1, "result": "AC", "execution_time": "2011 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef controlled_add(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.cp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range = QuantumRegister(1)\n    anc_pred = QuantumRegister(1)\n    qc.add_register(anc_range)\n    qc.add_register(anc_pred)\n\n    # case 1\n    qc.compose(oracle_less(n+1, s), [*regin, *anc_range], inplace=True)\n    qc.x(regin[-1])\n    qc.x(anc_range)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.compose(controlled_add(n, -s), [*regin[:-1], *anc_pred], inplace=True)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.x(anc_range)\n    qc.x(regin[-1])\n\n    # case 2\n    qc.compose(oracle_less(n+1, t), [*regin, *anc_range], inplace=True)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.compose(controlled_add(n+1, 2**(n+1)-t), [*regin, *anc_pred], inplace=True)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.x(anc_range)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A86D200016A73", "submission_order": 1, "result": "RE", "execution_time": "1858 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    # QFT\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    # B2\n    for i in range(n):\n        qc.cp(-2 * math.pi * s * 2 ** (i - n), n, i, ctrl_state=1)\n        qc.cp(-2 * math.pi * t * 2 ** (i - n), n, i, ctrl_state=0)\n\n    # IQFT\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-math.pi / 2 ** (i - j), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A86D200016A73", "submission_order": 2, "result": "WA", "execution_time": "1639 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    # QFT\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    # B2\n    for i in range(n):\n        qc.cp(-2 * math.pi * s * 2 ** (i - n), n, i, ctrl_state=1)\n        qc.cp(-2 * math.pi * t * 2 ** (i - n), n, i, ctrl_state=0)\n\n    # IQFT\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-math.pi / 2 ** (i - j), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A86D200016A73", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    # QFT\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    # B2\n    for i in range(n):\n        qc.cp(-2 * math.pi * s * 2 ** (i - n), n, i, ctrl_state=0)\n        qc.cp(-2 * math.pi * t * 2 ** (i - n), n, i, ctrl_state=1)\n\n    # IQFT\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-math.pi / 2 ** (i - j), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A86D200016A73", "submission_order": 4, "result": "AC", "execution_time": "2072 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    # QFT\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n\n    # B2\n    for i in range(n):\n        qc.cp(-2 * math.pi * s * 2 ** (i - n), n, i, ctrl_state=0)\n        qc.cp(-2 * math.pi * t * 2 ** (i - n), n, i, ctrl_state=1)\n\n    # IQFT\n    for i in reversed(range(n // 2)):\n        qc.swap(i, n - i - 1)\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-math.pi / 2 ** (i - j), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A92FDE8B505CB", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    QFT(qc, list(range(n))):\n        \n    for i in range(n):   \n        theta = 2 * math.pi * ((2 ** (n + 1)) - t) * (2 ** i) / (2 ** n) \n        qc.cp(theta, n, i)\n    \n    qc.x(n)\n\n    for i in range(n):\n        theta = 2 * math.pi * (-s) * (2 ** i) / (2 ** n)\n\n    qc.x(n)\n\n    QFT(qc, list(range(n)), inversed=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A92FDE8B505CB", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    QFT(qc, list(range(n))):\n        \n    for i in range(n):   \n        theta = 2 * math.pi * ((2 ** (n + 1)) - t) * (2 ** i) / (2 ** n) \n        qc.cp(theta, n, i)\n    \n    qc.x(n)\n\n    for i in range(n):\n        theta = 2 * math.pi * (-s) * (2 ** i) / (2 ** n)\n        qc.cp(theta, n, i)\n\n    qc.x(n)\n\n    QFT(qc, list(range(n)), inversed=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "A92FDE8B505CB", "submission_order": 3, "result": "AC", "execution_time": "1726 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    \n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    QFT(qc, list(range(n)))\n        \n    for i in range(n):   \n        theta = 2 * math.pi * ((2 ** (n + 1)) - t) * (2 ** i) / (2 ** n) \n        qc.cp(theta, n, i)\n    \n    qc.x(n)\n\n    for i in range(n):\n        theta = 2 * math.pi * (-s) * (2 ** i) / (2 ** n)\n        qc.cp(theta, n, i)\n\n    qc.x(n)\n\n    QFT(qc, list(range(n)), inversed=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AA7C91926226F", "submission_order": 1, "result": "WA", "execution_time": "1643 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n\n    def add(qc, n, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                        qc.mcx(list(range(i, j)) + [n], j)\n\n    def subtract(qc, n, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    qc.mcx(list(range(i, j)) + [n], j)\n\n    qc.cx(n-1, n)\n    subtract(qc, n, s)\n    qc.x(n)\n    subtract(qc, n, t)\n    qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AA7C91926226F", "submission_order": 2, "result": "WA", "execution_time": "1761 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n\n    def add(qc, n, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                        qc.mcx(list(range(i, j)) + [n], j)\n\n    def subtract(qc, n, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    qc.mcx(list(range(i, j)) + [n], j)\n\n    qc.cx(n-1, n)\n    subtract(qc, n, s)\n    qc.x(n)\n    subtract(qc, n, t)\n    #qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AA7C91926226F", "submission_order": 3, "result": "WA", "execution_time": "1728 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n\n    def add(qc, n, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                        qc.mcx(list(range(i, j)) + [n], j)\n\n    def subtract(qc, n, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    qc.mcx(list(range(i, j)) + [n], j)\n\n    qc.cx(n-1, n)\n    qc.x(n)\n    subtract(qc, n, s)\n    qc.x(n)\n    subtract(qc, n, t)\n    #qc.x(n)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AA7C91926226F", "submission_order": 4, "result": "WA", "execution_time": "1806 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n\n    def add(qc, n, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                        qc.mcx(list(range(i, j)) + [n], j)\n\n    def subtract(qc, n, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    qc.mcx(list(range(i, j)) + [n], j)\n    # initialize state to 5\n\n\n    qc.cx(n-1, n)\n    subtract(qc, n, s)\n    qc.x(n)\n    add(qc, n, 2**(n+1) - t)\n    qc.x(n)\n    \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AA7C91926226F", "submission_order": 5, "result": "RE", "execution_time": "1661 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n\n    def add(qc, n, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                        qc.mcx(list(range(i, j)) + [n], j)\n\n    def subtract(qc, n, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    qc.mcx(list(range(i, j)) + [n], j)\n    # initialize state to 7\n    for i in range(n):\n        if (k & (1 << i)):\n            qc.x(i)\n\n    add(qc, n, 2**(n+1)-t)\n    qc.x(n)\n    subtract(qc, n, s)\n    qc.x(n)\n    \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AA7C91926226F", "submission_order": 6, "result": "AC", "execution_time": "2352 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n\n    def add(qc, n, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                        qc.mcx(list(range(i, j)) + [n], j)\n\n    def subtract(qc, n, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    qc.mcx(list(range(i, j)) + [n], j)\n\n    add(qc, n, 2**(n+1)-t)\n    qc.x(n)\n    subtract(qc, n, s)\n    qc.x(n)\n    \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "ABA4478D057ED", "submission_order": 1, "result": "WA", "execution_time": "2141 ms", "memory": "163 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef b3(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft_n =qft(n)\n    \n    qc.compose(qft_n,k,inplace=True)\n    \n    for i in range(n):\n        theta = 2 * pi * a * 2**i / 2**n\n        qc.cp(theta,n, i)\n    \n    qc.compose(qft_n.inverse(),k,inplace=True)\n    return qc\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(n + 1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft_n =qft(n)\n    qc.compose(qft_n,k,inplace=True)\n    \n    for i in range(n):\n        tt = 2 * pi * (t-2**(n+1)) * 2**i / 2**n\n        qc.cp(tt,n, i)\n        qc.x(n)\n        ts=s\n        qc.cp(ts,n, i)\n        qc.x(0)        \n        \n    qc.compose(qft_n.inverse(),k,inplace=True)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "ABA4478D057ED", "submission_order": 2, "result": "WA", "execution_time": "1986 ms", "memory": "163 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef b3(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft_n =qft(n)\n    \n    qc.compose(qft_n,k,inplace=True)\n    \n    for i in range(n):\n        theta = 2 * pi * a * 2**i / 2**n\n        qc.cp(theta,n, i)\n    \n    qc.compose(qft_n.inverse(),k,inplace=True)\n    return qc\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(n + 1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft_n =qft(n)\n    qc.compose(qft_n,k,inplace=True)\n    \n    for i in range(n):\n        tt = 2 * pi * (t-2**(n+1)) * 2**i / 2**n\n        qc.cp(tt,n, i)\n        qc.x(n)\n        ts=2 * pi * s * 2**i / 2**n\n        qc.cp(ts,n, i)\n        qc.x(0)        \n        \n    qc.compose(qft_n.inverse(),k,inplace=True)\n    return qc.inverse()\n'''"}
{"problem": "QPC004_B4", "user": "ABA4478D057ED", "submission_order": 3, "result": "AC", "execution_time": "2203 ms", "memory": "163 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan\nfrom qiskit import QuantumCircuit,QuantumRegister\n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef b3(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft_n =qft(n)\n    \n    qc.compose(qft_n,k,inplace=True)\n    \n    for i in range(n):\n        theta = 2 * pi * a * 2**i / 2**n\n        qc.cp(theta,n, i)\n    \n    qc.compose(qft_n.inverse(),k,inplace=True)\n    return qc\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n    qft_n =qft(n)\n    qc.compose(qft_n,k,inplace=True)\n    \n    for i in range(n):\n        tt = 2 * pi * (t-2**(n+1)) * 2**i / 2**n\n        qc.cp(tt,n, i)\n        qc.x(n)\n        ts=2 * pi * s * 2**i / 2**n\n        qc.cp(ts,n, i)\n        qc.x(n)        \n        \n    qc.compose(qft_n.inverse(),k,inplace=True)\n    return qc.inverse()\n'''"}
{"problem": "QPC004_B4", "user": "ABC30E6D0AB4F", "submission_order": 1, "result": "AC", "execution_time": "2491 ms", "memory": "167 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(CU1Gate(pi/2**(j-i)), [j, i])\n    return qc\n\ndef addition(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(QFT(n), range(n), inplace=True)\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)), [i])\n    qc.compose(QFT(n).inverse(), range(n), inplace=True)\n    return qc\n\ndef B3(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # qc.x(n)\n    \n    qc.append(QFT(n).control(1), [n, *range(n)])\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)).control(1), [n, i])\n    qc.append(QFT(n).inverse().control(1), [n, *range(n)])\n \n    return qc.decompose(reps=2)\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(B3(n, -t), range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(B3(n, -s), range(n + 1), inplace=True)\n    qc.x(n)\n \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "ABCB39C3F2428", "submission_order": 1, "result": "WA", "execution_time": "1919 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n    # Define the range for k\n    lower_bound = s\n    upper_bound = 2**n\n    second_lower_bound = 2**n\n    second_upper_bound = t\n    \n    # Create a classical condition to check the ranges\n    # We will use the last qubit as an auxiliary qubit to help with the logic\n    # We will use the last qubit to indicate which operation to perform\n    \n    # For k in [s, 2^n)\n    for k in range(lower_bound, upper_bound):\n        # Convert k to binary and set the qubits accordingly\n        binary_k = format(k, f'0{n}b')[::-1]  # little-endian\n        for i in range(n):\n            if binary_k[i] == '1':\n                qc.x(i)  # Set the qubit to |1>\n        \n        # Apply the operation O: |k> -> |k - s>\n        # This is equivalent to subtracting s from k\n        # We need to apply a series of controlled NOTs to achieve this\n        binary_s = format(s, f'0{n}b')[::-1]  # little-endian\n        for i in range(n):\n            if binary_s[i] == '1':\n                qc.cx(i, n)  # Controlled NOT to subtract s\n        \n        # Reset the qubits to prepare for the next iteration\n        for i in range(n):\n            if binary_k[i] == '1':\n                qc.x(i)  # Reset the qubit to |0>\n    \n    # For k in [2^n, t)\n    for k in range(second_lower_bound, second_upper_bound):\n        # Convert k to binary and set the qubits accordingly\n        binary_k = format(k, f'0{n}b')[::-1]  # little-endian\n        for i in range(n):\n            if binary_k[i] == '1':\n                qc.x(i)  # Set the qubit to |1>\n        \n        # Apply the operation O: |k> -> |k + (2^(n+1) - t)>\n        # This is equivalent to adding (2^(n+1) - t) to k\n        addition = (2**(n + 1) - t)\n        binary_addition = format(addition, f'0{n}b')[::-1]  # little-endian\n        for i in range(n):\n            if binary_addition[i] == '1':\n                qc.cx(i, n)  # Controlled NOT to add (2^(n+1) - t)\n        \n        # Reset the qubits to prepare for the next iteration\n        for i in range(n):\n            if binary_k[i] == '1':\n                qc.x(i)  # Reset the qubit to |0>\n    \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AD8544A8C985D", "submission_order": 1, "result": "RE", "execution_time": "1911 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.append(constant_addition(n,-t), qargs=range(n+1))\n    qc.x(n)\n    qc.append(constant_addition(n,-s), qargs=range(n+1))\n    qc.x(n)\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AD8544A8C985D", "submission_order": 2, "result": "UGE", "execution_time": "1633 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.append(constant_addition(n,-t), qargs=range(n+1))\n    qc.x(n)\n    qc.append(constant_addition(n,-s), qargs=range(n+1))\n    qc.x(n)\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AD8544A8C985D", "submission_order": 3, "result": "UGE", "execution_time": "1751 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.append(constant_addition(n,-t), qargs=range(n+1))\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AD8544A8C985D", "submission_order": 4, "result": "UGE", "execution_time": "1629 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.append(constant_addition(n,-t), qargs=range(n+1))\n    qc.x(n)\n    qc.append(constant_addition(n,-s), qargs=range(n+1))\n    qc.x(n)\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AD8544A8C985D", "submission_order": 5, "result": "RE", "execution_time": "1802 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AD8544A8C985D", "submission_order": 6, "result": "RE", "execution_time": "1665 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AD8544A8C985D", "submission_order": 7, "result": "WA", "execution_time": "1689 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*(-t)/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AD8544A8C985D", "submission_order": 8, "result": "AC", "execution_time": "2142 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    # Write your code here:\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*(-t)/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    qc.x(n)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*(-s)/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    qc.x(n)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "ADB17C53F72BD", "submission_order": 1, "result": "WA", "execution_time": "1922 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import tau, pi\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    ctl = n\n    n -= 1\n\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(pi / (1 << (i - j)), j, i)\n\n    for i in range(n):\n        theta = tau / (1 << n - i)\n        # qc.cp(a * theta[i], k[n - 1 - i])\n        qc.cp(((1 << n + 1) - t - s) * theta, ctl, n - 1 - i)\n\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-pi / (1 << (i - j)), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AE3D05C9E2DB2", "submission_order": 1, "result": "RE", "execution_time": "1566 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for k in range(s, 2**n):\n        qc.cx(k, n)  \n\n    for k in range(2**n, t):\n        qc.cx(k, n) \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AE57912C6F34D", "submission_order": 1, "result": "WA", "execution_time": "1752 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n    # Apply the oracle O based on the conditions\n    for k in range(s + 1, 2**n):\n        # Apply the first condition for s < k < 2^n\n        # Example: Apply X gate to the last qubit if condition is met\n        qc.x(n)\n    \n    for k in range(2**n + 1, t):\n        # Apply the second condition for 2^n < k < t\n        # Example: Apply Y gate to the last qubit if condition is met\n        qc.y(n)\n    \n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AEDEB933D93EB", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "177 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    t = 2 ** (n + 1) - t\n    for j in range(t):\n        for i in range(n):\n            qc.cx(n, i)\n        qc.cx(n, 0)\n        for i in range(n - 1):\n            qc.mcx(list(range(0, i + 1)) + [n], i + 1)\n        for i in range(n):\n            qc.cx(n, i)\n    qc.x(n)\n    for j in range(s):\n        qc.cx(n, 0)\n        for i in range(n - 1):\n            qc.mcx(list(range(0, i + 1)) + [n], i + 1)\n    qc.x(n)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AEDEB933D93EB", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "171 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    t = 2 ** (n + 1) - t\n    for i in range(n):\n        qc.cx(n, i)\n    for j in range(t):\n        qc.cx(n, 0)\n        for i in range(n - 1):\n            qc.mcx(list(range(0, i + 1)) + [n], i + 1)\n    for i in range(n):\n        qc.cx(n, i)\n    qc.x(n)\n    for j in range(s):\n        qc.cx(n, 0)\n        for i in range(n - 1):\n            qc.mcx(list(range(0, i + 1)) + [n], i + 1)\n    qc.x(n)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AEDEB933D93EB", "submission_order": 3, "result": "WA", "execution_time": "1678 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    t = 2 ** (n + 1) - t\n    for i in range(n):\n        qc.cx(n, i)\n    for j in range(10):\n        if (t / (2 ** j)) % 2 == 1:\n            qc.cx(n, j)\n            for i in range(j, n - 1):\n                qc.mcx(list(range(j, i + 1)) + [n], i + 1)\n    for i in range(n):\n        qc.cx(n, i)\n    qc.x(n)\n    for j in range(10):\n        if (s / (2 ** j)) % 2 == 1:\n            qc.cx(n, j)\n            for i in range(j, n - 1):\n                qc.mcx(list(range(j, i + 1)) + [n], i + 1)\n    qc.x(n)\n    return qc\n'''"}
{"problem": "QPC004_B4", "user": "AEDEB933D93EB", "submission_order": 4, "result": "AC", "execution_time": "2218 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    t = 2 ** (n + 1) - t\n    for i in range(n):\n        qc.cx(n, i)\n    for j in range(10):\n        if (t // (2 ** j)) % 2 == 1:\n            qc.cx(n, j)\n            for i in range(j, n - 1):\n                qc.mcx(list(range(j, i + 1)) + [n], i + 1)\n    for i in range(n):\n        qc.cx(n, i)\n    qc.x(n)\n    for j in range(10):\n        if (s // (2 ** j)) % 2 == 1:\n            qc.cx(n, j)\n            for i in range(j, n - 1):\n                qc.mcx(list(range(j, i + 1)) + [n], i + 1)\n    qc.x(n)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3084D9D9EBBA", "submission_order": 1, "result": "WA", "execution_time": "1704 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(CU1Gate(pi/2**(j-i)), [j, i])\n    return qc\n\ndef B2(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(QFT(n), range(n), inplace=True)\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)), [i])\n    qc.compose(QFT(n).inverse(), range(n), inplace=True)\n    return qc\n\ndef B3(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # qc.x(n)\n    \n    qc.append(QFT(n).control(1), [n, *range(n)])\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)).control(1), [n, i])\n    qc.append(QFT(n).inverse().control(1), [n, *range(n)])\n \n    return qc.decompose(reps=2)\n\ndef B4(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(B3(n, -t), range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(B3(n, -s), range(n + 1), inplace=True)\n    qc.x(n)\n \n    return qc\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(B2(n+1, 2**n-a), range(n + 1), inplace=True)\n    qc.compose(B4(n, 2**n-a, 2**n-a+L), range(n + 1), inplace=True)\n    qc.compose(B2(n+1, L-a), range(n + 1), inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3084D9D9EBBA", "submission_order": 2, "result": "WA", "execution_time": "2066 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(CU1Gate(pi/2**(j-i)), [j, i])\n    return qc\n\ndef B2(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(QFT(n), range(n), inplace=True)\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)), [i])\n    qc.compose(QFT(n).inverse(), range(n), inplace=True)\n    return qc\n\ndef B3(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # qc.x(n)\n    \n    qc.append(QFT(n).control(1), [n, *range(n)])\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)).control(1), [n, i])\n    qc.append(QFT(n).inverse().control(1), [n, *range(n)])\n \n    return qc.decompose(reps=2)\n\ndef B4(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(B3(n, -t), range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(B3(n, -s), range(n + 1), inplace=True)\n    qc.x(n)\n \n    return qc\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(B2(n+1, 2**n-a), range(n + 1), inplace=True)\n    qc.compose(B4(n, 2**n-a, 2**n-a+L), range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(B2(n+1, -(2**n-a)), range(n + 1), inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3084D9D9EBBA", "submission_order": 3, "result": "AC", "execution_time": "2309 ms", "memory": "170 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(CU1Gate(pi/2**(j-i)), [j, i])\n    return qc\n\ndef B2(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(QFT(n), range(n), inplace=True)\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)), [i])\n    qc.compose(QFT(n).inverse(), range(n), inplace=True)\n    return qc\n\ndef B3(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # qc.x(n)\n    \n    qc.append(QFT(n).control(1), [n, *range(n)])\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)).control(1), [n, i])\n    qc.append(QFT(n).inverse().control(1), [n, *range(n)])\n \n    return qc.decompose(reps=2)\n\ndef B4(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(B3(n, -t), range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(B3(n, -s), range(n + 1), inplace=True)\n    qc.x(n)\n \n    return qc\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    a=L-a\n    # Write your code here:\n    qc.compose(B2(n+1, 2**n-a), range(n + 1), inplace=True)\n    qc.compose(B4(n, 2**n-a, 2**n-a+L), range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(B2(n+1, -2**n+L-a), range(n + 1), inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3636C48E5A68", "submission_order": 1, "result": "RE", "execution_time": "1768 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    x = QuantumRegister(1)\n    qc.add_bits(x)\n    qc.x(n+1)\n    qc.compose(constant_addition(n+1,q-L), inplace=True)\n    qc.compose(constant_addition(n,L), inplace=True)\n    qc.x(n+1)\n    qc.swap(n,n+1)\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3636C48E5A68", "submission_order": 2, "result": "RE", "execution_time": "1711 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    x = QuantumRegister(1)\n    qc.add_bits(x)\n    qc.x(n+1)\n    qc.compose(constant_addition(n+1,a-L), inplace=True)\n    qc.compose(constant_addition(n,L), inplace=True)\n    qc.x(n+1)\n    qc.swap(n,n+1)\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3636C48E5A68", "submission_order": 3, "result": "RE", "execution_time": "1635 ms", "memory": "156 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    x = QuantumRegister(1)\n    qc.add_bits(x)\n    qc.x(n+1)\n    qc.compose(constant_addition(n+1,a-L), inplace=True)\n    qc.compose(constant_addition(n,L), qubits=list(range(n+1)), inplace=True)\n    qc.x(n+1)\n    qc.swap(n,n+1)\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3636C48E5A68", "submission_order": 4, "result": "WA", "execution_time": "1773 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    x = QuantumRegister(1)\n    qc.add_bits(x)\n    qc.x(n+1)\n    qc.compose(constant_addition(n+1,a-L), inplace=True)\n    qc.compose(constant_addition(n,L), qubits=list(range(n+1)), inplace=True)\n    qc.x(n+1)\n    qc.swap(n,n+1)\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3636C48E5A68", "submission_order": 5, "result": "WA", "execution_time": "2026 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    x = QuantumRegister(1)\n    qc.add_bits(x)\n    qc.x(n+1)\n    qc.compose(constant_addition(n+1,a-L), inplace=True)\n    qc.compose(constant_addition(n,L), inplace=True)\n    qc.x(n+1)\n    qc.x(n)\n    return qc\n\ndef constant_addition(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3636C48E5A68", "submission_order": 6, "result": "WA", "execution_time": "2114 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\nimport math\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n,2^n-L+a), inplace=True)\n    qc.compose(pack(n,2^n-L+a,2^n+a), inplace=True)\n    qc.compose(add(n,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n,-t), inplace=True)\n    qc.x(n)\n    qc.compose(add(n,-s), inplace=True)\n    qc.x(n)\n    return qc\n\ndef add(n,a):\n    qc = QuantumCircuit(n+1)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    for i in range(n):\n        qc.cp(2*math.pi*a/2**(n-i),n,i)\n    for i in range(n-1,-1,-1):\n        qc.ch(n,i)\n        for j in range(i-1,-1,-1):\n            qc.mcp(-2*math.pi/2**(i-j+1),[n,j],i)\n    for k in range(n//2):\n        qc.cswap(n,k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A3636C48E5A68", "submission_order": 7, "result": "AC", "execution_time": "2443 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n+1,2**n-L+a), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(add(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(add(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    return qc\n\ndef add(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(-2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A38F6C5408787", "submission_order": 1, "result": "RE", "execution_time": "1649 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef add(qc, a):\n    for i in range(n):\n        if (a & (1 << i)):\n            n_not = n - i\n            for j in range(i+n_not-1, i-1, -1):\n                if j == i:\n                    qc.x(j)\n                else:\n                    qc.mcx(list(range(i, j)), j)\n\ndef subtract(qc, a):\n    for i in range(n-1, -1, -1):\n        if (a & (1 << i)):\n            n_not = n - i\n            for j in range(i, i+n_not):\n                if j == i:\n                    qc.x(j)\n                else:\n                    qc.mcx(list(range(i, j)), j)\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    subtract(qc, L-a)\n    add(qc, L)\n\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A38F6C5408787", "submission_order": 2, "result": "WA", "execution_time": "1730 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    def add(qc, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                    if j == i:\n                        qc.x(j)\n                    else:\n                        qc.mcx(list(range(i, j)), j)\n\n    def subtract(qc, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    if j == i:\n                        qc.x(j)\n                    else:\n                        qc.mcx(list(range(i, j)), j)\n\n    subtract(qc, L-a)\n    add(qc, L)\n\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A38F6C5408787", "submission_order": 3, "result": "WA", "execution_time": "1871 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    def add(qc, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                    if j == i:\n                        qc.x(j)\n                    else:\n                        qc.mcx(list(range(i, j)), j)\n\n    def subtract(qc, n, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    if j == i:\n                        qc.x(j)\n                    else:\n                        qc.mcx(list(range(i, j)), j)\n\n    subtract(qc, n+1, L-a)\n    add(qc, L)\n\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A38F6C5408787", "submission_order": 4, "result": "WA", "execution_time": "1814 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    def add(qc, n, a):\n        for i in range(n):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i+n_not-1, i-1, -1):\n                    if j == i:\n                        qc.x(j)\n                    else:\n                        qc.mcx(list(range(i, j)), j)\n\n    def subtract(qc, n, a):\n        for i in range(n-1, -1, -1):\n            if (a & (1 << i)):\n                n_not = n - i\n                for j in range(i, i+n_not):\n                    if j == i:\n                        qc.x(j)\n                    else:\n                        qc.mcx(list(range(i, j)), j)\n\n    subtract(qc, n+1,L-a)\n    add(qc, n+1, L)\n\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "A834A36AF9176", "submission_order": 1, "result": "WA", "execution_time": "1735 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n    # Convert a to binary representation\n    a_bin = format(a, f'0{n}b')  # Get binary representation of a with n bits\n    \n    # Add a to k using controlled operations\n    for i in range(n):\n        if a_bin[i] == '1':\n            # Apply a series of CNOT gates to add a to k\n            # The control is on the i-th qubit of the input k\n            # The target is the (n+1)-th qubit (which is the auxiliary qubit)\n            qc.cx(i, n)  # CNOT from k_i to auxiliary qubit\n    \n    # Now we need to handle the modulo L operation\n    # If L is a power of 2, we can simply ignore the overflow\n    # If L is not a power of 2, we need to implement a more complex logic\n    # However, since L <= 2^n, we can assume that the addition will not exceed the range of n bits\n    \n    # We will use a simple approach to ensure we do not exceed L\n    # This is a naive approach and may not be optimal for all cases\n    # We will check if the result exceeds L and apply a correction if necessary\n    \n    # This is a placeholder for the correction logic\n    # In practice, we would need to implement a more complex logic to handle the modulo correctly\n    \n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "ABBDEFBB7D433", "submission_order": 1, "result": "RE", "execution_time": "1498 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    b = 2 ** n - L + a\n    # add b\n    for i in range(n):\n        qc.x(i)\n    for j in range(10):\n        if (t // (2 ** j)) % 2 == 1:\n            qc.x(j)\n            for i in range(j, n - 1):\n                qc.mcx(list(range(j, i + 1)), i + 1)\n    for i in range(n):\n        qc.x(i)\n    qc.x(n)\n    for j in range(10):\n        if (L // (2 ** j)) % 2 == 1:\n            qc.cx(n, j)\n            for i in range(j, n - 1):\n                qc.mcx(list(range(j, i + 1)) + [n], i + 1)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "ABBDEFBB7D433", "submission_order": 2, "result": "RE", "execution_time": "1829 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    b = 2 ** n - L + a\n    # add b\n    for i in range(n):\n        qc.x(i)\n    for j in range(10):\n        if (b // (2 ** j)) % 2 == 1:\n            qc.x(j)\n            for i in range(j, n - 1):\n                qc.mcx(list(range(j, i + 1)), i + 1)\n    for i in range(n):\n        qc.x(i)\n    qc.x(n)\n    for j in range(10):\n        if (L // (2 ** j)) % 2 == 1:\n            qc.cx(n, j)\n            for i in range(j, n - 1):\n                qc.mcx(list(range(j, i + 1)) + [n], i + 1)\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "AC39981D0E44F", "submission_order": 1, "result": "WA", "execution_time": "2026 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef add(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n)\n    qc = QuantumCircuit(k)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.p(theta, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef controlled_add(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.cp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef lr_something(n: int, s: int, t: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range = QuantumRegister(1)\n    anc_pred = QuantumRegister(1)\n    qc.add_register(anc_range)\n    qc.add_register(anc_pred)\n\n    # case 1\n    qc.compose(oracle_less(n + 1, s), [*regin, *anc_range], inplace=True)\n    qc.x(regin[-1])\n    qc.x(anc_range)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.compose(controlled_add(n, -s), [*regin[:-1], *anc_pred], inplace=True)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.x(anc_range)\n    qc.x(regin[-1])\n\n    # case 2\n    qc.compose(oracle_less(n + 1, t), [*regin, *anc_range], inplace=True)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.compose(\n        controlled_add(n + 1, 2 ** (n + 1) - t), [*regin, *anc_pred], inplace=True\n    )\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.x(anc_range)\n\n    return qc\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range = QuantumRegister(1)\n    qc.add_register(anc_range)\n\n    qc.compose(add(n+1, a), inplace=True)\n    qc.x(anc_range)\n    qc.compose(oracle_less(n+1, L), inplace=True)\n    qc.compose(controlled_add(n+1, -L), inplace=True)\n    qc.compose(oracle_less(n+1, L-a-1), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "AC39981D0E44F", "submission_order": 2, "result": "AC", "execution_time": "2447 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef add(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n)\n    qc = QuantumCircuit(k)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.p(theta, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef controlled_add(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.cp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef lr_something(n: int, s: int, t: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range = QuantumRegister(1)\n    anc_pred = QuantumRegister(1)\n    qc.add_register(anc_range)\n    qc.add_register(anc_pred)\n\n    # case 1\n    qc.compose(oracle_less(n + 1, s), [*regin, *anc_range], inplace=True)\n    qc.x(regin[-1])\n    qc.x(anc_range)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.compose(controlled_add(n, -s), [*regin[:-1], *anc_pred], inplace=True)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.x(anc_range)\n    qc.x(regin[-1])\n\n    # case 2\n    qc.compose(oracle_less(n + 1, t), [*regin, *anc_range], inplace=True)\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.compose(\n        controlled_add(n + 1, 2 ** (n + 1) - t), [*regin, *anc_pred], inplace=True\n    )\n    qc.ccx(regin[-1], anc_range, anc_pred)\n    qc.x(anc_range)\n\n    return qc\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.x(anc_range1)\n    qc.compose(oracle_less(n+1, L), [*regin, *anc_range2], inplace=True)\n    qc.compose(oracle_less(n+1, L-a), [*regin, *anc_range1], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.compose(add(n+1, a), inplace=True)\n    qc.compose(controlled_add(n+1, -L), [*regin, *anc_range3], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.x(anc_range2)\n    qc.x(regin[-1])\n    qc.ccx(regin[-1], anc_range2, anc_range3)\n    qc.x(regin[-1])\n    qc.compose(controlled_add(n+1, L), [*regin, *anc_range3], inplace=True)\n\n    qc.compose(oracle_less(n+1, 2**(n+1) + 1 - L), [*regin, *anc_range3], inplace=True)\n    qc.compose(oracle_less(n+1, L), [*regin, *anc_range3], inplace=True)\n\n    qc.x(anc_range2)\n    qc.compose(oracle_less(n+1, L), [*regin, *anc_range2], inplace=True)\n\n    qc.compose(oracle_less(n+1, L), [*regin, *anc_range1], inplace=True)\n    qc.compose(oracle_less(n+1, a), [*regin, *anc_range1], inplace=True)\n    qc.x(anc_range1)\n\n    return qc\n'''"}
{"problem": "QPC004_B5", "user": "AD1257120C5DB", "submission_order": 1, "result": "WA", "execution_time": "1717 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC004_C1", "user": "A03329382C5C2", "submission_order": 1, "result": "RE", "execution_time": "1835 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(n):\n        result.append(a)\n        a *= a\n        a %= L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A03329382C5C2", "submission_order": 2, "result": "RE", "execution_time": "1756 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(100001):\n        result.append(a)\n        a *= a\n        a %= L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A03329382C5C2", "submission_order": 3, "result": "AC", "execution_time": "2931 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(n):\n        result.append(a)\n        a *= a\n        a %= L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A07C5B99F6451", "submission_order": 1, "result": "RE", "execution_time": "1481 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    for i in range(n):\n        result.append(n)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A07C5B99F6451", "submission_order": 2, "result": "RE", "execution_time": "1650 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    prev = a % L\n    result.append(a % L)\n\n    for i in range(1,n):\n        prev = prev * prev % L\n        result.append(prev)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A07C5B99F6451", "submission_order": 3, "result": "RE", "execution_time": "1783 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    prev = a % L\n    result.append(a % L)\n\n    for i in range(1,10**5):\n        prev = prev * prev % L\n        result.append(prev)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A07C5B99F6451", "submission_order": 4, "result": "RE", "execution_time": "1648 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    prev = a % L\n    result.append(a % L)\n\n    for i in range(1,10**5):\n        prev = prev * prev % L\n        result.append(prev)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A07C5B99F6451", "submission_order": 5, "result": "RE", "execution_time": "1614 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    x = a % L\n\n    for i in range(n):\n        result.append(x)\n        x = x * x % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A07C5B99F6451", "submission_order": 6, "result": "RE", "execution_time": "1677 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    x = a % L\n\n    for i in range(100):\n        result.append(x)\n        x = x * x % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A07C5B99F6451", "submission_order": 7, "result": "RE", "execution_time": "1557 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    global n\n\n    x = a % L\n\n    for i in range(n):\n        result.append(x)\n        x = x * x % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A110D66F2267D", "submission_order": 1, "result": "AC", "execution_time": "2871 ms", "memory": "191 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = [a]\n    # Write your code here:\n\n    for i in range(1, n):\n        result.append((result[i-1]*result[i-1]) % L)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A1AA3AFF00CDB", "submission_order": 1, "result": "AC", "execution_time": "2789 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    results = []\n    current = a % L  # a^1 mod L\n    for _ in range(n):\n        results.append(current)\n        current = (current * current) % L  # (a^(2^k) mod L) = (previous_result)^2 mod L\n    return results\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A1B87C154C2AA", "submission_order": 1, "result": "RE", "execution_time": "1921 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append((a**(2**k))%L)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A1B87C154C2AA", "submission_order": 2, "result": "RE", "execution_time": "1620 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(k):\n        result.append((a**(2**k))%L)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A1B87C154C2AA", "submission_order": 3, "result": "RE", "execution_time": "1465 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    ans=a%L\n    for k in range(n):\n        result.append(ans)\n        ans=(ans*ans)%L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A1B87C154C2AA", "submission_order": 4, "result": "AC", "execution_time": "2771 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    ans=a%L\n    for k in range(n):\n        result.append(ans)\n        ans=(ans*ans)%L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A288E7C112CF8", "submission_order": 1, "result": "RE", "execution_time": "1462 ms", "memory": "141 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    # [a, a^2, a^4, ...] (mod L)\n    x = a\n    for i in range(n):\n        result.add(x)\n        x = x * x % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A288E7C112CF8", "submission_order": 2, "result": "AC", "execution_time": "2262 ms", "memory": "175 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    # [a, a^2, a^4, ...] (mod L)\n    x = a\n    for i in range(n):\n        result.append(x)\n        x = x * x % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A2C260FBB3DF5", "submission_order": 1, "result": "RE", "execution_time": "1665 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    ans = a % L\n    result.append(ans)\n    for _ in range(n-1):\n        ans = (ans ** 2) % L\n        result.append(ans)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A2C260FBB3DF5", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\ndef solve(n:int a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    ans = a % L\n    result.append(ans)\n    for _ in range(n-1):\n        ans = (ans ** 2) % L\n        result.append(ans)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A2C260FBB3DF5", "submission_order": 3, "result": "AC", "execution_time": "2935 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    ans = a % L\n    result.append(ans)\n    for _ in range(n-1):\n        ans = (ans ** 2) % L\n        result.append(ans)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A2DA7620EFC41", "submission_order": 1, "result": "WA", "execution_time": "1765 ms", "memory": "161 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result = []\n    power = 1  # Start with a^(2^0) which is just 'a'\n    \n    for _ in range(n):\n        result.append(power % L)\n        power = (power * power) % L  # Squaring the power each time\n        \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A2DA7620EFC41", "submission_order": 2, "result": "RE", "execution_time": "1667 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    \n    # Calculate initial value a^1 mod L\n    current = a % L\n    \n    # For each power of 2, square the previous result\n    # This efficiently calculates a^(2^k) mod L for k = 0,1,2,...,n-1\n    while len(result) < n:\n        result.append(current)\n        current = (current * current) % L\n        \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A2DA7620EFC41", "submission_order": 3, "result": "WA", "execution_time": "1659 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int, n: int) -> list[int]:\n    result = []\n    power = 1  # a^0 = 1\n    for _ in range(n):\n        result.append(power % L)\n        power = (power * a) % L  # Using modular multiplication to avoid overflow\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A2DA7620EFC41", "submission_order": 4, "result": "RE", "execution_time": "1649 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result = []\n    current = a  # Start with a^1\n    \n    for _ in range(n):  # Compute up to a^(2^(n-1))\n        result.append(current % L)\n        current = pow(current, 2, L)  # Efficient modular exponentiation\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A2DA7620EFC41", "submission_order": 5, "result": "WA", "execution_time": "1797 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int, n: int) -> list[int]:\n    result: list[int] = []\n    current = 1\n    for k in range(1, n):\n        current = (current * a) % L\n        result.append(current)\n    return result\n\n# Example usage:\n# a = 3\n# L = 7\n# n = 5\n# print(solve(a, L, n))  # Output: [3, 2, 6, 4]\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 1, "result": "RE", "execution_time": "2084 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    x = a % L  \n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 2, "result": "RE", "execution_time": "1554 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    x = a % L  \n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 3, "result": "RE", "execution_time": "1502 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    n = int(input().strip())\n\n    x = a % L  \n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 4, "result": "RE", "execution_time": "1609 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    i = 1\n    n = 0\n    while i < L:\n        i <<= 1  \n        n += 1 \n    x = a % L  \n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 5, "result": "RE", "execution_time": "1786 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    i = 1\n    n = 0\n    while i < L:\n        i <<= 1  \n        n += 1 \n    n -= 1\n    x = a % L  \n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 6, "result": "RE", "execution_time": "1685 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    i = 1\n    n = 0\n    while i < L:\n        i <<= 1  \n        n += 1 \n    n -= 1\n    x = a % L  \n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 7, "result": "RE", "execution_time": "1665 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    i = 1\n    n = 0\n    while i < L:\n        i << 1  \n        n += 1 \n    n -= 1\n    x = a % L  \n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 8, "result": "RE", "execution_time": "1651 ms", "memory": "158 MiB", "code": "'''python\ndef gcd(x: int, y: int) -> int:\n    while y != 0:\n        x, y = y, x % y\n    return x\n\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    \n\n    i = 1\n    n = 0\n    while i < L:\n        i << 1  \n        n += 1 \n    n -= 1\n\n    while n > 0:\n        if gcd(n, a) == 1 and gcd(n, L) == 1:\n            break\n        n -= 1\n        \n    x = a % L  \n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 9, "result": "RE", "execution_time": "1640 ms", "memory": "158 MiB", "code": "'''python\ndef gcd(x: int, y: int) -> int:\n    while y != 0:\n        x, y = y, x % y\n    return x\n\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    n=10*10*10*10*10\n        \n    x = a % L  \n    for _ in range(1,n+1):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 10, "result": "RE", "execution_time": "1593 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here\n        \n    x = a % L  \n    for _ in range(1,n+1):\n        result.append(x)\n        x = (x * x) % L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 11, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit.quantum_info import Statevector\nfrom qiskit.visualization import *\nfrom qiskit import QuantumCircuit\ndef ccx_same(qc, c1, c2, tgt):\n\n    qc.cx(c2, tgt)    \n    qc.cx(c1, c2)    \n    qc.cx(c2, tgt)    \n    qc.cx(c1, c2)    \n\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here\n\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n - 1):\n        qc.cx(i, i+1)\n        ccx_same(qc, i, i+1, i) \n\n    qc.x(n - 1)\n\n    for i in reversed(range(n - 1)):\n        ccx_same(qc, i, i+1, i)\n        qc.cx(i, i+1)\n\n    for i in range(n):\n        qc.x(i)\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 12, "result": "RE", "execution_time": "1485 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef ccx_same(qc, c1, c2, tgt):\n\n    qc.cx(c2, tgt)    \n    qc.cx(c1, c2)    \n    qc.cx(c2, tgt)    \n    qc.cx(c1, c2)    \n\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here\n\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n - 1):\n        qc.cx(i, i+1)\n        ccx_same(qc, i, i+1, i) \n\n    qc.x(n - 1)\n\n    for i in reversed(range(n - 1)):\n        ccx_same(qc, i, i+1, i)\n        qc.cx(i, i+1)\n\n    for i in range(n):\n        qc.x(i)\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 13, "result": "WA", "execution_time": "1988 ms", "memory": "162 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list:\n    result = [a]\n    for i in range(n - 1):\n        result.append(result[i-1] ** 2 % L)\n \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A325389273CBE", "submission_order": 14, "result": "AC", "execution_time": "3000 ms", "memory": "191 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list:\n    result = [a]\n    for i in range(1,n):\n        result.append(result[i-1] ** 2 % L)\n \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A3DA23F0F67F0", "submission_order": 1, "result": "AC", "execution_time": "2708 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a)\n        a=(a**2)%L\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 1, "result": "RE", "execution_time": "1468 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    k = 1\n    while True:\n        x = pow(a, 2**k, mod=L)\n        if x == a:\n            break\n        if(x == 1):\n            break\n        result.append(x)\n        k += 1\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 2, "result": "RE", "execution_time": "1500 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    k = 1\n    while True:\n        x = pow(a, pow(2, k), mod=L)\n        if x == a:\n            break\n        if(x == 1):\n            break\n        result.append(x)\n        k += 1\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 3, "result": "RE", "execution_time": "1528 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    k = 1\n    while True:\n        x = pow(a, k, mod=L)\n        if x == a:\n            break\n        if (x == 1):\n            break\n        if (result[-1] == x):\n            break\n        result.append(x)\n        k *= 2\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 4, "result": "RE", "execution_time": "1747 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a) # 2^0 \n    k = 2 # 2^1\n    while True:\n        x = pow(a, k, mod=L)\n        if x == a:\n            break\n        if (x == 1):\n            break\n        if (result[-1] == x):\n            break\n        result.append(x)\n        k *= 2\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a) # 2^0 \n    k = 2 # 2^1\n    while True:\n        x = pow(a, k, mod=L)\n        if (x == a || x == 1 || x == 0):\n            break\n        if (result[-1] == x):\n            break\n        result.append(x)\n        k *= 2\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 6, "result": "RE", "execution_time": "1696 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    k = 1\n    for i in range(10^5):\n        x = pow(a, k, mod=L)\n        result.append(x)\n        k *= 2\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 7, "result": "RE", "execution_time": "1647 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(10**5):\n        x = pow(a, pow(2, k), mod=L)\n        result.append(x)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 8, "result": "TLE", "execution_time": "3000 ms", "memory": "157 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(10**5):\n        x = pow(a, pow(2, k), mod=L)\n        result.append(x)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 9, "result": "WA", "execution_time": "1596 ms", "memory": "164 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    x = a % L\n    result.append(x)\n    for k in range(1, 10**5):\n        x = (x * 2) % L \n        result.append(x)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 10, "result": "WA", "execution_time": "1994 ms", "memory": "164 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(10**5):\n        x = pow(a, 2*k, mod=L)\n        result.append(x)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 11, "result": "WA", "execution_time": "1863 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        x = pow(a, 2*k, mod=L)\n        result.append(x)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 12, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        x = pow(a, pow(2, k), mod=L)\n        result.append(x)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 13, "result": "RE", "execution_time": "1615 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        x = pow(x, 2, mod=L)\n        result.append(x)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45D89576E194", "submission_order": 14, "result": "AC", "execution_time": "2863 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    x = a\n    result.append(x)\n    for k in range(1, n):\n        x = pow(x, 2, mod=L)\n        result.append(x)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 1, "result": "RE", "execution_time": "1820 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result = [pow(a, 2**k, L) for k in range(n)]\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 2, "result": "RE", "execution_time": "1953 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append(pow(a, 2**k, L))\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 3, "result": "RE", "execution_time": "1624 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append(pow(a, 2**k, L))\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport sympy.ntheory.factor_\n\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    L_totient = int(sympy.ntheory.factor_.totient(L))\n    for k in range(n):\n        tmp = pow(2, k, L_totient)\n        result.append(pow(a, tmp, L))\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 5, "result": "RE", "execution_time": "1583 ms", "memory": "157 MiB", "code": "'''python\ndef phi(num):\n    cnt=0\n    for i in range (1,num):\n        if gcd(num,i)==1:\n            cnt+=1\n    return cnt\n\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    L_totient = phi(L)\n    for k in range(n):\n      tmp = pow(2, k, L_totient)\n      result.append(pow(a, tmp, L))\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 6, "result": "RE", "execution_time": "1567 ms", "memory": "157 MiB", "code": "'''python\nfrom math import gcd\n\ndef phi(num):\n    cnt=0\n    for i in range (1,num):\n        if gcd(num,i)==1:\n            cnt+=1\n    return cnt\n\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    L_totient = phi(L)\n    for k in range(n):\n      tmp = pow(2, k, L_totient)\n      result.append(pow(a, tmp, L))\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 7, "result": "RE", "execution_time": "1489 ms", "memory": "158 MiB", "code": "'''python\nfrom math import gcd\n\ndef phi(num):\n    cnt=0\n    for i in range (1,num):\n        if gcd(num,i)==1:\n            cnt+=1\n    return cnt\n\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    L_totient = phi(L)\n    for k in range(n):\n        tmp = pow(2, k, L_totient)\n        result.append(pow(a, tmp, L))\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom math import gcd\n\ndef phi(num):\n    cnt=0\n    for i in range (1,num):\n        if gcd(num,i)==1:\n            cnt+=1\n    return cnt\n\ndef solve(n int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    L_totient = phi(L)\n    for k in range(n):\n        tmp = pow(2, k, L_totient)\n        result.append(pow(a, tmp, L))\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A45DCC4B2BED7", "submission_order": 9, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\nfrom math import gcd\n\ndef phi(num):\n    cnt=0\n    for i in range (1,num):\n        if gcd(num,i)==1:\n            cnt+=1\n    return cnt\n\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    L_totient = phi(L)\n    for k in range(n):\n        tmp = pow(2, k, L_totient)\n        result.append(pow(a, tmp, L))\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 1, "result": "RE", "execution_time": "1563 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    for i in range(n):\n        tmp = a**(2**i) % L\n        result.append(tmp)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 2, "result": "RE", "execution_time": "2037 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    for i in range(n):\n        tmp = (a**(2**i)) % L\n        result.append(tmp)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 3, "result": "RE", "execution_time": "1656 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a% L\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 4, "result": "RE", "execution_time": "1529 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a\n    for _ in range(n):\n        result.append(current % L)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 5, "result": "RE", "execution_time": "1635 ms", "memory": "159 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a\n    for _ in range(n):\n        result.append(current % L)\n        current = (current * current) % L\n\n    return result[:n]\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 6, "result": "RE", "execution_time": "1542 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a % L\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 7, "result": "RE", "execution_time": "1670 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    \n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 8, "result": "RE", "execution_time": "1476 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 9, "result": "RE", "execution_time": "1556 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a % L\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 10, "result": "RE", "execution_time": "1656 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a % L\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 11, "result": "RE", "execution_time": "1722 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 12, "result": "RE", "execution_time": "1546 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    current = a\n    for _ in range(n):\n        result.append(current)\n        current = pow(current, 2, L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 13, "result": "RE", "execution_time": "1621 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    x = a % L\n    for _ in range(n):\n        result.append(x)\n        # Square x modulo L for the next term\n        x = (x * x) % L  # or x = pow(x, 2, L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 14, "result": "RE", "execution_time": "1669 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    x = a % L\n    for _ in range(n-1):\n        result.append(x)\n        # Square x modulo L for the next term\n        x = (x * x) % L  # or x = pow(x, 2, L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 15, "result": "RE", "execution_time": "1695 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    x = a\n    for _ in range(n-1):\n        result.append(x)\n        # Square x modulo L for the next term\n        x = (x * x) % L  # or x = pow(x, 2, L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 16, "result": "RE", "execution_time": "1477 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    x = a\n    for _ in range(n):\n        result.append(x)\n        # Square x modulo L for the next term\n        x = (x * x) % L  # or x = pow(x, 2, L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 17, "result": "RE", "execution_time": "1488 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    result = [a]\n    for _ in range(n - 1):\n        result.append(result[-1] ** 2 % L)\n \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A4DB3E4437F45", "submission_order": 18, "result": "TLE", "execution_time": "3000 ms", "memory": "179 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list:\n    result = [a]\n    for _ in range(n - 1):\n        result.append(result[-1] ** 2 % L)\n \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A56F812424B13", "submission_order": 1, "result": "TOE", "execution_time": "", "memory": "", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    res = [1]\n    cur = 1\n    for i in range(1, n):\n        cur = cur * cur\n        if(cur >= L) cur = cur % L\n        res.push_back(cur)\n    return res\n'''"}
{"problem": "QPC004_C1", "user": "A56F812424B13", "submission_order": 2, "result": "RE", "execution_time": "1907 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    res = [1]\n    expmod = pow(a, -1, L)\n    curexp = 1\n    for i in range(1, n):\n        curexp = (2*curexp) % expmod\n        res.push_back(pow(a, curexp, L))\n    return res\n'''"}
{"problem": "QPC004_C1", "user": "A56F812424B13", "submission_order": 3, "result": "RE", "execution_time": "2063 ms", "memory": "157 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    expmod = pow(a, -1, L)\n    curexp = 1\n    for i in range(n):\n        curexp = (2*curexp) % expmod\n        res.push_back(pow(a, curexp, L))\n    return res\n'''"}
{"problem": "QPC004_C1", "user": "A56F812424B13", "submission_order": 4, "result": "RE", "execution_time": "2111 ms", "memory": "157 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    expmod = pow(a, -1, L)\n    curexp = 1\n    res = []\n    for i in range(n):\n        curexp = (2*curexp) % expmod\n        res.push_back(pow(a, curexp, L))\n    return res\n'''"}
{"problem": "QPC004_C1", "user": "A56F812424B13", "submission_order": 5, "result": "TOE", "execution_time": "", "memory": "", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    expmod = pow(a, -1, L)\n    curexp = 1\n    res =\n    for i in range(n):\n        curexp = (2*curexp) % expmod\n        res.append(pow(a, curexp, L))\n    return res\n'''"}
{"problem": "QPC004_C1", "user": "A56F812424B13", "submission_order": 6, "result": "AC", "execution_time": "2702 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    res = [1]*n\n    cur = a\n    for i in range(n):\n        res[i] = cur\n        cur = (cur*cur)%L\n    return res\n'''"}
{"problem": "QPC004_C1", "user": "A58513FBB174E", "submission_order": 1, "result": "RE", "execution_time": "1900 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result: list[int] = []\n    current_value = a  \n    \n    for k in range(L):  \n        result.append(current_value % L)\n        current_value = (current_value * a * a) % L  \n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A58513FBB174E", "submission_order": 2, "result": "RE", "execution_time": "1474 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    current_value = a % L  \n    result.append(current_value)\n    \n    for k in range(1, n):\n        current_value = (current_value * current_value) % L\n        result.append(current_value)\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A58513FBB174E", "submission_order": 3, "result": "RE", "execution_time": "1585 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    current_value = a % L  \n    result.append(current_value)\n    \n    max_k = L.bit_length() \n    \n    for k in range(1, max_k):\n        current_value = (current_value * current_value) % L\n        result.append(current_value)\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A58513FBB174E", "submission_order": 4, "result": "RE", "execution_time": "1584 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    current_value = a % L  \n    result.append(current_value)\n    \n    max_k = 100000  # 最大回数として適当な大きな値（問題の制約に基づく）\n    \n    for k in range(1, max_k):\n        current_value = (current_value * current_value) % L\n        result.append(current_value)\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A58513FBB174E", "submission_order": 5, "result": "RE", "execution_time": "1765 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    current_value = a % L  \n    result.append(current_value)\n    \n    for _ in range(n):\n        result.append(current % L)\n        current = (current * current) % L\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A58513FBB174E", "submission_order": 6, "result": "RE", "execution_time": "1561 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append(current)\n        current = (current ** 2) % L\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A58513FBB174E", "submission_order": 7, "result": "RE", "execution_time": "1739 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append(current)\n        current = (current ** 2) % L\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A58513FBB174E", "submission_order": 8, "result": "AC", "execution_time": "2696 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    current = a % L  # 初期値 a^2^0 mod L (a^1 mod L)\n    \n    for k in range(n):\n        result.append(current)\n        # 次の a^(2^(k+1)) mod L を計算\n        current = (current ** 2) % L\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 1, "result": "RE", "execution_time": "1800 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result = pow(a, 2**k, )\n        results.append(result)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 2, "result": "RE", "execution_time": "1728 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    current = a % L\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 3, "result": "RE", "execution_time": "1518 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    current = a % L\n    n = 2 ** 1024\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 4, "result": "RE", "execution_time": "1548 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    current = a % L\n    n = 10 ** 5\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 5, "result": "RE", "execution_time": "1700 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    current = a % L\n    n = 10 ** 5\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 6, "result": "RE", "execution_time": "1783 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    if not (1 <= a < L <= 2**1024):\n        raise ValueError(\"条件 1 ≤ a < L ≤ 2^1024 を満たしていません。\")\n    current = a % L\n    n = 10 ** 5\n    for _ in range(n):\n        result.append(current)\n        current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 7, "result": "RE", "execution_time": "1781 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    if not (1 <= a < L <= 2**1024):\n        raise ValueError(\"条件 1 ≤ a < L ≤ 2^1024 を満たしていません。\")\n        current = a % L\n        n = 10 ** 5\n        for _ in range(n):\n            result.append(current)\n            current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 8, "result": "RE", "execution_time": "1765 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    if not (1 <= a < L <= 2**1024):\n        raise ValueError(\"条件 1 ≤ a < L ≤ 2^1024 を満たしていません。\")\n        current = a % L\n        n = 10 ** 5\n        for _ in range(n):\n            result.append(current)\n            current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 9, "result": "RE", "execution_time": "2029 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    result = [a]\n    for _ in range(n - 1):\n        result.append(result[-1] ** 2 % L)\n \n    return result\n    if not (1 <= a < L <= 2**1024):\n        raise ValueError(\"条件 1 ≤ a < L ≤ 2^1024 を満たしていません。\")\n        current = a % L\n        n = 10 ** 5\n        for _ in range(n):\n            result.append(current)\n            current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 10, "result": "RE", "execution_time": "2013 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result = [a]\n    for _ in range(n - 1):\n        result.append(result[-1] ** 2 % L)\n \n    return result\n    if not (1 <= a < L <= 2**1024):\n        raise ValueError(\"条件 1 ≤ a < L ≤ 2^1024 を満たしていません。\")\n        current = a % L\n        n = 10 ** 5\n        for _ in range(n):\n            result.append(current)\n            current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A5D72ED9B3B0C", "submission_order": 11, "result": "AC", "execution_time": "2844 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result = [a]\n    for _ in range(n - 1):\n        result.append(result[-1] ** 2 % L)\n \n    return result\n    if not (1 <= a < L <= 2**1024):\n        raise ValueError(\"条件 1 ≤ a < L ≤ 2^1024 を満たしていません。\")\n        current = a % L\n        n = 10 ** 5\n        for _ in range(n):\n            result.append(current)\n            current = (current * current) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A65FF65626F92", "submission_order": 1, "result": "AC", "execution_time": "2914 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    \n    v = a\n    for i in range(n):\n    \tresult.append(v)\n    \tv = (v ** 2) % L\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A7D2F4F917E4D", "submission_order": 1, "result": "AC", "execution_time": "3000 ms", "memory": "191 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(n):\n        result.append(a)\n        a = a * a % L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A83F97D36C67B", "submission_order": 1, "result": "AC", "execution_time": "2833 ms", "memory": "191 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    \n    current_value = 1  # This will hold a^(2^k) mod L, starting with a^(2^0) = a^1 mod L\n    for k in range(n):\n        if k == 0:\n            current_value = a % L  # a^(2^0) mod L\n        else:\n            current_value = (current_value * current_value) % L  # a^(2^k) = (a^(2^(k-1)))^2 mod L\n        \n        result.append(current_value)\n    \n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8645A240690F", "submission_order": 1, "result": "RE", "execution_time": "1505 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    val = a\n    result.append(val % L)\n    for i in range(k):\n        val = (a ** 2) % L\n        result.append(val)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8645A240690F", "submission_order": 2, "result": "WA", "execution_time": "1701 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    val = a\n    result.append(val % L)\n    for i in range(n):\n        val = (a ** 2) % L\n        result.append(val)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8645A240690F", "submission_order": 3, "result": "WA", "execution_time": "1571 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    val = a\n    result.append(val % L)\n    for i in range(n):\n        val = (val ** 2) % L\n        result.append(val)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8645A240690F", "submission_order": 4, "result": "AC", "execution_time": "2797 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    val = a\n    result.append(val % L)\n    for i in range(n - 1):\n        val = (val ** 2) % L\n        result.append(val)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8BAEB1214037", "submission_order": 1, "result": "RE", "execution_time": "1580 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(n):\n        result.append(a % L)\n        a = a * a\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8BAEB1214037", "submission_order": 2, "result": "RE", "execution_time": "1578 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(n):\n        result.append(a % L)\n        a = (a * a) % L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8BAEB1214037", "submission_order": 3, "result": "WA", "execution_time": "1706 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int, n: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(n):\n        result.append(a % L)\n        a = (a * a) % L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8BAEB1214037", "submission_order": 4, "result": "WA", "execution_time": "1823 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int, n: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(n):\n        result.append(a)\n        a = (a * a) % L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A8BAEB1214037", "submission_order": 5, "result": "AC", "execution_time": "2658 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for _ in range(n):\n        result.append(a)\n        a = (a * a) % L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A94EC2CC80C4D", "submission_order": 1, "result": "AC", "execution_time": "2870 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    x = a % L\n    for _ in range(n):\n        result.append(x)\n        x = (x * x) % L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A984ED6CAEC0E", "submission_order": 1, "result": "AC", "execution_time": "2950 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n\n    for _ in range(n):\n        result.append(a)\n        a = (a * a) % L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A9AF297F479D2", "submission_order": 1, "result": "RE", "execution_time": "1567 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    record = {}\n    i = 0\n    while True:\n        a2modL = pow(a, 2**i, L)\n        if a2modL in record:\n            break\n        record[a2modL] = i\n        result.append(a2modL)\n        i += 1\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A9AF297F479D2", "submission_order": 2, "result": "RE", "execution_time": "1549 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    \n    record = {}\n    val = a % L\n    i = 0\n\n    while val not in record:\n        record[val] = i\n        result.append(val)\n        val = (val * a) % L\n        i += 1\n\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A9C49DF13D7A2", "submission_order": 1, "result": "AC", "execution_time": "2976 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a)\n        a *= a\n        a %= L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A9F06D68C38B4", "submission_order": 1, "result": "RE", "execution_time": "1794 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a % L)\n    for i in range(n - 1):\n        result.append((result[i] * result[i]) % L)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "A9F06D68C38B4", "submission_order": 2, "result": "AC", "execution_time": "2732 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a % L)\n    for i in range(n - 1):\n        result.append((result[i] * result[i]) % L)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AA909D5BEC6B5", "submission_order": 1, "result": "RE", "execution_time": "1560 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a)\n        a = a*a%L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AA909D5BEC6B5", "submission_order": 2, "result": "AC", "execution_time": "2862 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a)\n        a = a*a%L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "ACF5EBCBA447E", "submission_order": 1, "result": "AC", "execution_time": "2702 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    b = a\n    for i in range(0, n):\n        if i > 0:\n            b = b*b\n            b %= L\n        b %= L\n        result += [b]\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD602DA575EDA", "submission_order": 1, "result": "RE", "execution_time": "1698 ms", "memory": "156 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append((a ** (2 ** k)) % k)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD602DA575EDA", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append((a ** (2 ** k)) % L)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD602DA575EDA", "submission_order": 3, "result": "TLE", "execution_time": "3000 ms", "memory": "161 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append(a)\n        a = a * a\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD602DA575EDA", "submission_order": 4, "result": "AC", "execution_time": "2716 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append(a)\n        a = (a * a) % L\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 1, "result": "RE", "execution_time": "1525 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    n = 10**5\n    act = a\n    result.append(act)\n    for i in range(1, n):\n        act = pow(act, 2, L)\n        result.append(act)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 2, "result": "RE", "execution_time": "1904 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    n = int(input())\n    act = a\n    result.append(act)\n    for i in range(1, n):\n        act = pow(act, 2, L)\n        result.append(a)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 3, "result": "WA", "execution_time": "2235 ms", "memory": "160 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    act = a\n    result.append(act)\n    for i in range(1, n):\n        act = pow(act, 2, L)\n        result.append(a)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 4, "result": "WA", "execution_time": "1810 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    act = a\n    result.append(act)\n    for i in range(1, n-1):\n        act = pow(a, 2, L)\n        result.append(a)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 5, "result": "WA", "execution_time": "1647 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    act = a\n    result.append(act)\n    for i in range(1, n-1):\n        act = pow(act, 2, L)\n        result.append(a)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 6, "result": "WA", "execution_time": "1703 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    act = a\n    result.append(act)\n    for i in range(1, n-1):\n        act = act**2 % L\n        result.append(a)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 7, "result": "WA", "execution_time": "1766 ms", "memory": "164 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    act = a\n    result.append(act)\n    for i in range(1, n-1):\n        act = act**2 % L\n        result.append(act)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 8, "result": "RE", "execution_time": "1582 ms", "memory": "157 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    act = a\n    result.append(act)\n    for i in range(0, n-1):\n        act = act**2 % L\n        result.append(ac)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AD83A66F52985", "submission_order": 9, "result": "AC", "execution_time": "2951 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    act = a\n    result.append(act)\n    for i in range(n-1):\n        act = act**2 % L\n        result.append(act)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "ADEC3ACD2C70C", "submission_order": 1, "result": "AC", "execution_time": "2895 ms", "memory": "191 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    for i in range(1,n):\n        result.append(result[-1]**2%L)\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE07079D9535D", "submission_order": 1, "result": "RE", "execution_time": "1671 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    result.append(a % L)\n    for i in range(100000):\n        last = result[-1]\n        result.append(last*last % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE07079D9535D", "submission_order": 2, "result": "RE", "execution_time": "2009 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a, L):\n    result = []\n    result.append(a % L)\n    for i in range(100000):\n        last = result[-1]\n        result.append(last*last % L)\n\n    return result\n\n\nsolve(10, 13)\n'''"}
{"problem": "QPC004_C1", "user": "AE07079D9535D", "submission_order": 3, "result": "WA", "execution_time": "1775 ms", "memory": "164 MiB", "code": "'''python\ndef solve(n, a, L):\n    result = []\n    result.append(a % L)\n    for i in range(n):\n        last = result[-1]\n        result.append(last*last % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE07079D9535D", "submission_order": 4, "result": "AC", "execution_time": "2883 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n, a, L):\n    result = []\n    result.append(a % L)\n    for i in range(n-1):\n        last = result[-1]\n        result.append(last*last % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE081D378696E", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "159 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a**(2**(i))%L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE081D378696E", "submission_order": 2, "result": "AC", "execution_time": "2675 ms", "memory": "193 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a % L)\n    for i in range(1, n):\n        result.append(result[-1]**2 % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE12CC5569977", "submission_order": 1, "result": "WA", "execution_time": "1888 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int, n: int) -> list[int]:\n    result: list[int] = []\n    \n    result.append(a)\n    \n    for i in range(1, n):\n        result.append(pow(result[i - 1], 2, L))\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE453A9CBA36B", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a):\n        a = (a*a)%L;\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE453A9CBA36B", "submission_order": 2, "result": "RE", "execution_time": "1969 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a)\n        a = (a*a)%L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE453A9CBA36B", "submission_order": 3, "result": "AC", "execution_time": "2878 ms", "memory": "192 MiB", "code": "'''python\ndef solve(n:int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a)\n        a = (a*a)%L\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE8FC8BF70196", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for i in range(n):\n        result.append(a**(2**i) % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AE8FC8BF70196", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "160 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = [a**(2**i) % L for i in range(n)]\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AEBE90D991F1A", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "145 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n\n    if n == 1:\n        return result\n\n    for i in range(n-1):\n        result.append(result[-1] * a**(2**i))\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AEBE90D991F1A", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "143 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n\n\n    for i in range(n-1):\n        result.append(result[-1] * a**(2**i) % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AEBE90D991F1A", "submission_order": 3, "result": "AC", "execution_time": "2380 ms", "memory": "175 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n\n\n    for i in range(n-1):\n        result.append(result[-1] ** 2 % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AEFCF629DBBD5", "submission_order": 1, "result": "WA", "execution_time": "1899 ms", "memory": "143 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AEFCF629DBBD5", "submission_order": 2, "result": "WA", "execution_time": "1744 ms", "memory": "143 MiB", "code": "'''python\ndef solve(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AF9FD71BF7073", "submission_order": 1, "result": "RE", "execution_time": "1738 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append(a**(2**k) % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AF9FD71BF7073", "submission_order": 2, "result": "WA", "execution_time": "1763 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int, n:int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    for k in range(n):\n        result.append(a**(2**k) % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AF9FD71BF7073", "submission_order": 3, "result": "WA", "execution_time": "1790 ms", "memory": "160 MiB", "code": "'''python\ndef solve(a: int, L: int, n:int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    n = 10\n    for k in range(n):\n        result.append(a**(2**k) % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AF9FD71BF7073", "submission_order": 4, "result": "RE", "execution_time": "1470 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    n = 1\n    for k in range(n):\n        result.append(a**(2**k) % L)\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AF9FD71BF7073", "submission_order": 5, "result": "WA", "execution_time": "1672 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int, n:int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    k = 0\n    while True:\n        if a >= L:\n            a %= L\n        result.append(a)\n\n        a **= 2\n        k += 1\n        if k == n:\n            break\n\n    return result\n'''"}
{"problem": "QPC004_C1", "user": "AF9FD71BF7073", "submission_order": 6, "result": "RE", "execution_time": "1605 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    k = 0\n    while True:\n        if a >= L:\n            a %= L\n        result.append(a)\n\n        a **= 2\n        k += 1\n        if k == n:\n            break\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A0A8908519E40", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    test = 1\n    while test % a != 0:\n        test += L\n    result = test // a\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A0A8908519E40", "submission_order": 2, "result": "WA", "execution_time": "1627 ms", "memory": "158 MiB", "code": "'''python\ndef expansion_euclid(a: int, b: int) -> [int,int,int]:\n    if b == 0:\n        return a,1,0\n    gcd,x1,y1 = expansion_euclid(b, a % b)\n    x = x1\n    y = x1 - (a // b) * y1\n    return gcd,x,y\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    _,X,_ = expansion_euclid(a,L)\n    return X % L\n'''"}
{"problem": "QPC004_C2", "user": "A0A8908519E40", "submission_order": 3, "result": "AC", "execution_time": "1847 ms", "memory": "158 MiB", "code": "'''python\ndef expansion_euclid(a: int, b: int) -> [int,int,int]:\n    if b == 0:\n        return a, 1, 0\n    gcd, x1, y1 = expansion_euclid(b, a % b)\n    x = y1\n    y = x1 - (a // b) * y1\n    return gcd, x, y\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    _, X, _ = expansion_euclid(a, L)\n    return X % L\n'''"}
{"problem": "QPC004_C2", "user": "A1181B21C7581", "submission_order": 1, "result": "AC", "execution_time": "1912 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n\n    # 拡張ユークリッドの互除法\n    def extended_gcd(x, y):\n        if y == 0:\n            return 1, 0\n        s, t = extended_gcd(y, x % y)\n        return t, s - (x // y) * t\n\n    x, _ = extended_gcd(a, L)\n\n    result = x % L\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A1CC146361C53", "submission_order": 1, "result": "AC", "execution_time": "1826 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = pow(a, -1, L)\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A29F1C1D13735", "submission_order": 1, "result": "AC", "execution_time": "1843 ms", "memory": "158 MiB", "code": "'''python\ndef extgcd(a, b):\n    if b:\n        d, y, x = extgcd(b, a % b)\n        y -= (a // b) * x\n        return d, x, y\n    return a, 1, 0\n\ndef solve(a: int, L: int) -> int:\n    _, x, _ = extgcd(a, L)\n\n    return x % L\n'''"}
{"problem": "QPC004_C2", "user": "A2D404E7FC939", "submission_order": 1, "result": "AC", "execution_time": "1723 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result=pow(a,-1,L)\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A367F108D3107", "submission_order": 1, "result": "RE", "execution_time": "1972 ms", "memory": "158 MiB", "code": "'''python\nx, y = 0, 1\n\ndef gcdExtended(a, b):\n    global x, y\n\n    if (a == 0):\n        x = 0\n        y = 1\n        return b\n    \n    gcd = gcdExtended(b % a, a)\n    x1 = x\n    y1 = y\n\n    x = y1 - (b // a) * x1\n    y = x1\n\n    return gcd\n    \ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    g = gcdExtended(A, M)\n    if (g != 1):\n        print(\"Inverse doesn't exist\")\n    else:\n        res = (x % M + M) % M\n    g = gcdExtended(A, M)\n    result = (x % M + M) % M\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A367F108D3107", "submission_order": 2, "result": "RE", "execution_time": "1677 ms", "memory": "158 MiB", "code": "'''python\nx, y = 0, 1\n\ndef gcdExtended(a, b):\n    global x, y\n\n    if (a == 0):\n        x = 0\n        y = 1\n        return b\n    \n    gcd = gcdExtended(b % a, a)\n    x1 = x\n    y1 = y\n\n    x = y1 - (b // a) * x1\n    y = x1\n\n    return gcd\n    \ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    g = gcdExtended(A, M)\n    if (g != 1):\n        print(\"Inverse doesn't exist\")\n    else:\n        res = (x % M + M) % M\n    g = gcdExtended(A, M)\n    result = (x % M + M) % M\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A367F108D3107", "submission_order": 3, "result": "AC", "execution_time": "1708 ms", "memory": "158 MiB", "code": "'''python\nx, y = 0, 1\ndef gcdExtended(a, b):\n    global x, y\n\n    if a == 0:\n        x = 0\n        y = 1\n        return b\n    gcd = gcdExtended(b % a, a)\n    x1 = x\n    y1 = y\n\n    x = y1 - (b // a) * x1\n    y = x1\n\n    return gcd\n\ndef solve(a: int, L: int) -> int:\n    global x, y\n    g = gcdExtended(a, L)\n    if g != 1:\n        return -1  \n    result = (x % L + L) % L\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A42D554836CE1", "submission_order": 1, "result": "AC", "execution_time": "1847 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    _,X,_ = extended_euclid(a,L)\n    return X % L\ndef extended_euclid(a: int, b: int) -> tuple[int,int,int]:\n    if b == 0:\n        return a,1,0\n    gcd,x1,y1 = extended_euclid(b,a%b)\n    x = y1\n    y = x1 - (a // b) * y1\n    return gcd,x,y\n'''"}
{"problem": "QPC004_C2", "user": "A4C1DED22C7E0", "submission_order": 1, "result": "AC", "execution_time": "1632 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = pow(a, -1, L)\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A592E09ABA386", "submission_order": 1, "result": "AC", "execution_time": "1752 ms", "memory": "158 MiB", "code": "'''python\ndef extended_gcd(a, b):\n    if a == 0:\n        return b, 0, 1\n    else:\n        g, x, y = extended_gcd(b % a, a)\n        return g, y - (b // a) * x, x\n\ndef solve(a: int, L: int) -> int:\n    g, x, y = extended_gcd(a, L)\n    if g != 1:\n        return None  # Modular inverse doesn't exist if a and L are not coprime\n    else:\n        return x % L\n\n# Example usage:\na = 3\nL = 11\nprint(solve(a, L))  # Output should be 4, since 3 * 4 mod 11 = 1\n'''"}
{"problem": "QPC004_C2", "user": "A5BFDB3B79AC7", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    p = 0\n    while True:\n        if (p*L + 1) % a == 0:\n            result = (p*L + 1) // a\n            break\n        p += 1\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A616000848340", "submission_order": 1, "result": "AC", "execution_time": "2102 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    return pow(a, -1, L)\n'''"}
{"problem": "QPC004_C2", "user": "A64CFBF41851C", "submission_order": 1, "result": "RE", "execution_time": "1902 ms", "memory": "156 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = pow(a,calculate_totient(N)-1,L)\n\n    return result\n\ndef find_divisors(n):\n    divisors = []\n    for i in range(1, int(n**0.5) + 1):\n        if n % i == 0:\n            divisors.append(i)\n            if i != n // i:  # 同じ約数を二重に追加しない\n                divisors.append(n // i)\n    return sorted(divisors)\n\ndef calculate_totient(N):\n    if N == 1:\n        print(1)\n    else:\n        N_factor = find_divisors(N)[1:]\n        totient = N\n        while N_factor:\n            totient = (totient*(N_factor[0]-1))//N_factor[0]\n            N_factor = [k for k in N_factor if k % N_factor[0] != 0]\n    return totient\n'''"}
{"problem": "QPC004_C2", "user": "A64CFBF41851C", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "156 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = pow(a,calculate_totient(L)-1,L)\n\n    return result\n\ndef find_divisors(n):\n    divisors = []\n    for i in range(1, int(n**0.5) + 1):\n        if n % i == 0:\n            divisors.append(i)\n            if i != n // i:  # 同じ約数を二重に追加しない\n                divisors.append(n // i)\n    return sorted(divisors)\n\ndef calculate_totient(N):\n    if N == 1:\n        print(1)\n    else:\n        N_factor = find_divisors(N)[1:]\n        totient = N\n        while N_factor:\n            totient = (totient*(N_factor[0]-1))//N_factor[0]\n            N_factor = [k for k in N_factor if k % N_factor[0] != 0]\n    return totient\n'''"}
{"problem": "QPC004_C2", "user": "A64CFBF41851C", "submission_order": 3, "result": "TLE", "execution_time": "3000 ms", "memory": "156 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    return pow(a, calculate_totient(L) - 1, L)\n\ndef calculate_totient(n: int) -> int:\n    result = n\n    p = 2\n    while p * p <= n:\n        if n % p == 0:\n            while n % p == 0:\n                n //= p\n            result -= result // p  # φ(n) *= (1 - 1/p)\n        p += 1\n    if n > 1:\n        result -= result // n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A64CFBF41851C", "submission_order": 4, "result": "RE", "execution_time": "2081 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = pow(a,calculate_totient(L)-1,L)\n\n    return result\n\ndef find_prime_factors(n):\n    factors = []\n    is_prime = [True] * (int(n**0.5) + 1)\n    is_prime[0:2] = [False,False]\n    for i in range(int(n**0.5) + 1):\n        if is_prime[i]:\n            for j in range(2*i,int(n**0.5) + 1,i):\n                is_prime[j] = False \n            if n % i == 0:\n                factors.append(i)\n                while n % i == 0:\n    \t              n //= i\n    if n > 1:\n        factors.append(n)\n    return factors\n\ndef calculate_totient(N):\n    if N == 1:\n        print(1)\n    else:\n        prime_factors = find_prime_factors(N)\n        totient = N\n        for p in prime_factors:\n            totient -= totient//p\n    return totient\n'''"}
{"problem": "QPC004_C2", "user": "A64CFBF41851C", "submission_order": 5, "result": "AC", "execution_time": "2398 ms", "memory": "156 MiB", "code": "'''python\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n \n \ndef solve(a: int, L: int) -> int:\n    _, x, _ = extended_euclidean(a, L)\n \n    return x % L\n'''"}
{"problem": "QPC004_C2", "user": "A6C475D5681BA", "submission_order": 1, "result": "AC", "execution_time": "1785 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    def egcd(a: int, b: int):\n        if b == 0:\n            return (a, 1, 0)\n        g, x, y = egcd(b, a % b)\n        return (g, y, x - (a // b) * y)\n    \n    # a と L は互いに素なので gcd(a, L) = 1\n    g, x, _ = egcd(a, L)\n    # xが a の逆元 (mod L) であるが、負の場合もあるので正の値に変換\n    result = x % L\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A6FBDD6160002", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    \n    def extgcd(a,b):\n\t  d = a\n\t  if b != 0:\n\t    d,(y,x) = extgcd(b,a % b)\n\t    y -= (a//b) * x\n\t  else:\n\t    x = 1\n\t    y = 0\n\t  return d,(x,y)\n\n    _,(v,_) = extgcd(a,L)\n    v = (v + L) % L\n    result = v\n \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A6FBDD6160002", "submission_order": 2, "result": "RE", "execution_time": "1742 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    \n    def extgcd(a,b):\n      d = a\n      if b != 0:\n      \td,(y,x) = extgcd(b,a % b)\n      \ty -= (a//b) * x\n      else:\n      \tx = 1\n      \ty = 0\n      return d,(x,y)\n\n    _,(v,_) = extgcd(a,L)\n    v = (v + L) % L\n    result = v\n'''"}
{"problem": "QPC004_C2", "user": "A6FBDD6160002", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    \n    import sys\n    sys.setrecursionlimit(10000)\n    \n    def extgcd(a,b):\n      d = a\n      if b != 0:\n      \td,(y,x) = extgcd(b,a % b)\n      \ty -= (a//b) * x\n      else:\n      \tx = 1\n      \ty = 0\n      return d,(x,y)\n\n    _,(v,_) = extgcd(a,L)\n    v = (v + L) % L\n    result = v\n \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A6FBDD6160002", "submission_order": 4, "result": "AC", "execution_time": "1789 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    # copied from https://qiita.com/akebono-san/items/f00c0db99342a8d68e5d :pray:\n    a,b = a,L    \n    x, y, u, v = 1, 0, 0, 1\n    while b:\n        k = a // b\n        x -= k * u\n        y -= k * v\n        x, u = u, x\n        y, v = v, y\n        a, b = b, a % b\n\n    \n    x = (x + L) % L\n    result = x\n \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A6FEC4807363A", "submission_order": 1, "result": "WA", "execution_time": "1681 ms", "memory": "157 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    # Write your code here:\n    for i in range(L - 1):\n        if (a ** i) % L == 1:\n            return i - 1\n'''"}
{"problem": "QPC004_C2", "user": "A6FEC4807363A", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    # Write your code here:\n    for i in range(1, L):\n        if (a ** i) % L == 1:\n            return a ** (i - 1) % L\n'''"}
{"problem": "QPC004_C2", "user": "A6FEC4807363A", "submission_order": 3, "result": "RE", "execution_time": "1568 ms", "memory": "157 MiB", "code": "'''python\ndef extended_gcd(a, b):\n    if b == 0:\n        return a, 1, 0\n    gcd, x1, y1 = extended_gcd(b, a % b)\n    x = y1\n    y = x1 - (a // b) * y1\n    return gcd, x, y\n\n\ndef mod_inverse(a, L):\n    gcd, x, _ = extended_gcd(a, L)\n    if gcd != 1:\n        raise ValueError()\n    return x % L\n'''"}
{"problem": "QPC004_C2", "user": "A6FEC4807363A", "submission_order": 4, "result": "AC", "execution_time": "1821 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    return pow(a, -1, L)\n'''"}
{"problem": "QPC004_C2", "user": "A7054D908A792", "submission_order": 1, "result": "RE", "execution_time": "1795 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    m0, m1 = L, a\n    y0, y1 = 0, 1\n\n    while m1:\n        m0, m1 = m1, m0 % m1\n        y0, y1 = y1, y0 - y1 * (m0 // m1)\n\n    if y0 < 0:\n        y0 += L // m0\n\n    result = y0  \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A7054D908A792", "submission_order": 2, "result": "AC", "execution_time": "1761 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    def extended_gcd(x, y):\n        if y == 0:\n            return x, 1, 0\n        gcd, x1, y1 = extended_gcd(y, x % y)\n        return gcd, y1, x1 - (x // y) * y1\n\n    # a と L の最大公約数が 1 であれば逆元が存在\n    gcd, x, y = extended_gcd(a, L)\n\n    result = x % L  \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A7A5A066F8CAE", "submission_order": 1, "result": "WA", "execution_time": "1901 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    result = pow(a -1, L)\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A7A5A066F8CAE", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom math import *\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    result = math.pow(a -1, L)\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A7A5A066F8CAE", "submission_order": 3, "result": "RE", "execution_time": "1786 ms", "memory": "157 MiB", "code": "'''python\ndef extgcd(x, y):\n\n    if y == 0:\n        return (1, 0, x)\n    else:\n        s1, t1, g = extgcd(y, x % y)\n\n        s = t1\n        t = s1 - (x // y) * t1\n        return (s, t, g)\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    result = s%L\n    s, t, g = extgcd(a, L)\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A7A5A066F8CAE", "submission_order": 4, "result": "AC", "execution_time": "2108 ms", "memory": "158 MiB", "code": "'''python\ndef extgcd(x, y):\n\n    if y == 0:\n        return (1, 0, x)\n    else:\n        s1, t1, g = extgcd(y, x % y)\n\n        s = t1\n        t = s1 - (x // y) * t1\n        return (s, t, g)\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    \n    s, t, g = extgcd(a, L)\n\n    result = s%L\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A8C7CD27DBF7A", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\ndef gcd(a, b):\n    if b == 0:\n        return a\n    return gcd(b, a % b)\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    if gcd(a, L) > 1:\n      \n        # modulo inverse does not exist\n        return -1\n    for X in range(1, L):\n        if (((a % L) * (X % L)) % L == 1):\n            return X\n    return -1\n\n    # return result\n'''"}
{"problem": "QPC004_C2", "user": "A8C7CD27DBF7A", "submission_order": 2, "result": "AC", "execution_time": "1597 ms", "memory": "158 MiB", "code": "'''python\nx, y = 0, 1\n\ndef gcdExtended(a, b):\n    global x, y\n\n    # Base Case\n    if (a == 0):\n        x = 0\n        y = 1\n        return b\n\n    # To store results of recursive call\n    gcd = gcdExtended(b % a, a)\n    x1 = x\n    y1 = y\n\n    # Update x and y using results of recursive\n    # call\n    x = y1 - (b // a) * x1\n    y = x1\n\n    return gcd\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    g = gcdExtended(a, L)\n    if (g != 1):\n        result = -1\n\n    else:\n        result = (x % L + L) % L\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A9190E613FF8E", "submission_order": 1, "result": "AC", "execution_time": "1972 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    return pow(a, -1, L)\n'''"}
{"problem": "QPC004_C2", "user": "A94E938F47B9A", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    for b in range(L):\n        if a*b % L == 1:\n            return b\n    #return result\n'''"}
{"problem": "QPC004_C2", "user": "A94E938F47B9A", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    for b in range(L):\n        if a*b % L == 1:\n            return b\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A94E938F47B9A", "submission_order": 3, "result": "AC", "execution_time": "1902 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    return pow(a, -1, L)\n    #return result\n'''"}
{"problem": "QPC004_C2", "user": "A9C4FD3C72271", "submission_order": 1, "result": "WA", "execution_time": "1632 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    if L == 1:\n        result = 0\n    else:\n        result = 1\n \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A9C4FD3C72271", "submission_order": 2, "result": "AC", "execution_time": "2424 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    \n    i0, i = a, L\n    j0, j = 1, 0\n    while i != 0:\n        q = i0 // i\n        i0, i = i, i0 - q * i\n        j0, j = j, j0 - q * j\n    \n    result = j0 % L\n    \n \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "A9C85310D45C9", "submission_order": 1, "result": "WA", "execution_time": "1591 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> list[int]:\n    result: int = 0\n    # Write your code here:\n    result = 1\n    l = L-2\n    while(l > 0):\n        if(l%2 == 1):\n            result = (result*a)%L\n        a  = (a*a)%L\n        l = int(l/2)\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "AA456D687BBD6", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    for i in range(1, L):\n        if (((a % L) * (a % L)) % L == 1):\n            return i\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "AA456D687BBD6", "submission_order": 2, "result": "RE", "execution_time": "1716 ms", "memory": "158 MiB", "code": "'''python\ndef extended_gcd(a, b):\n    if a == 0:\n        return (b, 0, 1)\n    else:\n        g, x, y = extended_gcd(b % a, a)\n        return (g, y - (b // a) * x, x)\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    g, x, y = extended_gcd(a, L)\n    return x % m\n'''"}
{"problem": "QPC004_C2", "user": "AA456D687BBD6", "submission_order": 3, "result": "AC", "execution_time": "1789 ms", "memory": "158 MiB", "code": "'''python\ndef extended_gcd(a, b):\n    if a == 0:\n        return (b, 0, 1)\n    else:\n        g, x, y = extended_gcd(b % a, a)\n        return (g, y - (b // a) * x, x)\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    g, x, y = extended_gcd(a, L)\n    return x % L\n'''"}
{"problem": "QPC004_C2", "user": "AAB8ECE506040", "submission_order": 1, "result": "AC", "execution_time": "1788 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n\n    return pow(a, -1, L)\n'''"}
{"problem": "QPC004_C2", "user": "ABDB2A97AF84F", "submission_order": 1, "result": "RE", "execution_time": "1780 ms", "memory": "158 MiB", "code": "'''python\nfrom math import pow\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result =pow(a,-1,L)\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ABDB2A97AF84F", "submission_order": 2, "result": "AC", "execution_time": "1698 ms", "memory": "158 MiB", "code": "'''python\ndef extGCD(a, b) :\n    if b ==  0 :\n        return a, 1, 0\n    d, y, x = extGCD(b, a%b)\n    y -= a//b * x\n    return d, x, y\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    d,x,y=extGCD(a,L)\n    result =x\n    if result<0:\n        result+=L\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ABDEEDD3E1B41", "submission_order": 1, "result": "AC", "execution_time": "1995 ms", "memory": "156 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    \n    def extended_gcd(a: int, b: int):\n        if a == 0:\n            return b, 0, 1\n        gcd, x1, y1 = extended_gcd(b % a, a)\n        x = y1 - (b // a) * x1\n        y = x1\n        return gcd, x, y\n    \n    gcd, x, y = extended_gcd(a, L)\n    \n    # Since a and L are coprime, gcd should be 1\n    if gcd != 1:\n        raise ValueError(\"a and L are not coprime\")\n    \n    # x is the modular inverse, we need to ensure it's positive\n    result = x % L\n    \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ABF5573C7413F", "submission_order": 1, "result": "AC", "execution_time": "1825 ms", "memory": "158 MiB", "code": "'''python\n# gcd(a, b)とax+by=gcd(a,b)を満たすx,yを返す\ndef euclidean(a, b):\n    x = w = 1\n    y = z = 0\n    while b:\n        q = a // b\n        r = a % b\n\n        x, y, z, w = z, w, x - q * z, y - q * w\n        a, b = b, r\n\n    return a, x, y\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    _, x, _ = euclidean(a, L)\n    result = x % L\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ACDA3A7E160D0", "submission_order": 1, "result": "RE", "execution_time": "1694 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    for k in range(n):\n        result = pow(a, 2**k, L)\n        results.append(result)\n    \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ACDA3A7E160D0", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    def extended_gcd(a,b):\n        gcd, x1, y1 = extended_gcd(b % a,a)\n        x = y1 - (b // a) * x1\n        y = x1\n        return gcd, x, y\n\n    gcd, x, _ = extended_gcd(a,L)\n    if gcd != 1:\n        raise ValueError(\"互いに素で無いため逆元が存在しない。\")\n    else result = x % L\n    \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ACDA3A7E160D0", "submission_order": 3, "result": "AC", "execution_time": "1737 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    def extended_gcd(a,b):\n        if a == 0:\n            return b,0,1\n        gcd, x1, y1 = extended_gcd(b % a,a)\n        x = y1 - (b // a) * x1\n        y = x1\n        return gcd, x, y\n\n    gcd, x, _ = extended_gcd(a,L)\n    if gcd != 1:\n        raise ValueError(\"互いに素で無いため逆元が存在しない。\")\n    else:\n        result = x % L\n    \n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ACFCBD4C80E15", "submission_order": 1, "result": "RE", "execution_time": "1434 ms", "memory": "140 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    x = 0\n    L0 = L\n    y = 0\n    \n    while (a > 1):\n        q = a // L\n        t = m\n        m = a % m\n        a = t\n        t = y\n        y = x - q * y\n        x = t\n    \n    if (x < 0):\n        x = x + L0\n\n    return x\n'''"}
{"problem": "QPC004_C2", "user": "ACFCBD4C80E15", "submission_order": 2, "result": "RE", "execution_time": "1517 ms", "memory": "140 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    x = 0\n    L0 = L\n    y = 0\n    \n    while (a > 1):\n        q = a // L\n        t = m\n        L = a % L\n        a = t\n        t = y\n        y = x - q * y\n        x = t\n    \n    if (x < 0):\n        x = x + L0\n\n    return x\n'''"}
{"problem": "QPC004_C2", "user": "ACFCBD4C80E15", "submission_order": 3, "result": "WA", "execution_time": "1441 ms", "memory": "140 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    x = 0\n    L0 = L\n    y = 0\n    \n    while (a > 1):\n        q = a // L\n        t = L\n        L = a % L\n        a = t\n        t = y\n        y = x - q * y\n        x = t\n    \n    if (x < 0):\n        x = x + L0\n\n    return x\n'''"}
{"problem": "QPC004_C2", "user": "ACFCBD4C80E15", "submission_order": 4, "result": "AC", "execution_time": "1641 ms", "memory": "141 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    x = 1\n    L0 = L\n    y = 0\n    \n    while (a > 1):\n        q = a // L\n        t = L\n        L = a % L\n        a = t\n        t = y\n        y = x - q * y\n        x = t\n    \n    if (x < 0):\n        x = x + L0\n\n    return x\n'''"}
{"problem": "QPC004_C2", "user": "ADB4B0BC5FA96", "submission_order": 1, "result": "WA", "execution_time": "1471 ms", "memory": "158 MiB", "code": "'''python\ndef power(a,b,m):\n    result = 1\n    while b > 0:\n        if b % 2 != 0:\n            result = (result * a) % m\n        b //= 2\n        a = (a * a) % m\n\n    return result\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = power(a, L-2, L)\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ADB4B0BC5FA96", "submission_order": 2, "result": "WA", "execution_time": "1789 ms", "memory": "158 MiB", "code": "'''python\ndef power(a,b,m):\n    result = 1\n    a %= m\n    while b > 0:\n        if b % 2 != 0:\n            result = (result * a) % m\n        b //= 2\n        a = (a * a) % m\n    result %= m\n    return result\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = power(a, L-2, L)\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ADB4B0BC5FA96", "submission_order": 3, "result": "AC", "execution_time": "2328 ms", "memory": "158 MiB", "code": "'''python\ndef extended_euclidean(X,Y):\n    if X<Y:\n        b, a, GCD = extended_euclidean(Y,X)\n    \n    x = X\n    y = Y\n    a = d = 1\n    b = c = 0\n\n    while y>0:\n        q = x//y\n        r = x%y\n        if r==0: break # GCD 구해짐\n        x,y,a,b,c,d = y,r,c,d,a-q*c,b-q*d\n\n    return c,d,y\n\n\n\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    x,y,GCD = extended_euclidean(a, L)\n    result = (x+L*1000)%L\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "ADD2B7DFE8ADC", "submission_order": 1, "result": "AC", "execution_time": "1986 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = pow(a, -1, L)\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "AEAE9A87FB663", "submission_order": 1, "result": "AC", "execution_time": "1712 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    \n    result = pow(a, -1, L)\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "AF209BC1E092E", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = 1\n    while True:\n        if ((result * a) % L) == 1:\n            break\n        else:\n            result = (result * a) % L\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "AF209BC1E092E", "submission_order": 2, "result": "AC", "execution_time": "1779 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    result = result = pow(a, -1, mod=L)\n\n    return result\n'''"}
{"problem": "QPC004_C2", "user": "AF97A819D9535", "submission_order": 1, "result": "AC", "execution_time": "1811 ms", "memory": "158 MiB", "code": "'''python\ndef solve(a: int, L: int) -> int:\n    result: int = 0\n    # Write your code here:\n    def extended_gcd(x: int, y: int):\n        if y == 0:\n            return (1, 0, x)\n        x2, y2, g = extended_gcd(y, x % y)\n        return (y2, x2 - (x // y) * y2, g)\n    \n    x, _, g = extended_gcd(a, L)\n    result = x % L\n    \n    return result\n'''"}
{"problem": "QPC004_C3", "user": "A12A28AA50C30", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "174 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate, CU1Gate\n\n\"\"\"\nYou can apply oracle as follows:\nqc.compose(o, inplace=True)\n\n\"\"\"\n\ndef QFT(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n//2):\n        qc.swap(i, n-i-1)\n    for i in range(n):\n        qc.h(i)\n        for j in range(i+1, n):\n            qc.append(CU1Gate(pi/2**(j-i)), [j, i])\n    return qc\n\ndef B2(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.compose(QFT(n), range(n), inplace=True)\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)), [i])\n    qc.compose(QFT(n).inverse(), range(n), inplace=True)\n    return qc\n\ndef B3(n: int, a: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(k, c)\n    # qc.x(n)\n    \n    qc.append(QFT(n).control(1), [n, *range(n)])\n    for i in range(n):\n        qc.append(PhaseGate(2*pi*a*(1/2)**(n-i)).control(1), [n, i])\n    qc.append(QFT(n).inverse().control(1), [n, *range(n)])\n \n    return qc.decompose(reps=2)\n\ndef B4(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(B3(n, -t), range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(B3(n, -s), range(n + 1), inplace=True)\n    qc.x(n)\n \n    return qc\n\ndef B5(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    a=L-a\n    # Write your code here:\n    qc.compose(B2(n+1, 2**n-a), range(n + 1), inplace=True)\n    qc.compose(B4(n, 2**n-a, 2**n-a+L), range(n + 1), inplace=True)\n    qc.x(n)\n    qc.compose(B2(n+1, -2**n+L-a), range(n + 1), inplace=True)\n \n    return qc\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.compose(B5(n, a, L).control(1), [i] + list(range(n, n + n + 1)), inplace=True)\n        a += a\n        a %= L\n \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A3A70AB7DC992", "submission_order": 1, "result": "WA", "execution_time": "1801 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x = QuantumRegister(n)  # Register for x\n    y = QuantumRegister(n + 1)  # Register for y (n + 1 qubits)\n    qc = QuantumCircuit(x, y)\n\n    # We will use a series of controlled additions to implement the oracle\n    for x_value in range(0, L):\n        # Calculate ax mod L\n        ax_mod_L = (a * x_value) % L\n        \n        # Convert x_value to binary and apply controlled addition\n        for i in range(n):\n            if (x_value >> i) & 1:  # If the i-th bit of x_value is 1\n                # We need to add ax_mod_L to y\n                # We will add ax_mod_L to y using controlled operations\n                for j in range(n + 1):\n                    if (ax_mod_L >> j) & 1:  # If the j-th bit of ax_mod_L is 1\n                        # Apply a controlled NOT gate to add the j-th bit of ax_mod_L to y\n                        qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A8675F16998A9", "submission_order": 1, "result": "RE", "execution_time": "1644 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    for i in range(x):\n        if (a >> i) & 1:  # Check if the i-th bit of 'a' is 1\n            for j in range(ny):\n                oracle.append(CXGate(), [x + j, i])  # Controlled-X from y to x\n\n    # Add the y register to the result (modular addition is handled implicitly by Qiskit)\n    for i in range(y):\n        oracle.append(CXGate(), [x + y + i, x + i])  # Controlled-X from output to x\n\n    # Apply the modular reduction (mod L) if L < 2^n\n    if L < 2**n:\n        # Implement modular reduction using subtraction and conditional flips\n        for i in range(n - 1, -1, -1):\n            if (L >> i) & 1:  # Check if the i-th bit of L is 1\n                for j in range(i):\n                    oracle.append(CXGate(), [x + y + j, x + y + i])  # Controlled-X from lower bits to i-th bit\n\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 1, "result": "WA", "execution_time": "1928 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    # Create quantum registers for x and y\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    \n    # Create quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # We need to implement: |x⟩|y⟩ → |x⟩|(y + ax) mod L⟩\n    \n    # For each bit position i in x register\n    for i in range(n):\n        # Control on x[i] being 1\n        # If x[i] is 1, add (2^i * a) mod L to y\n        controlled_value = (pow(2, i) * a) % L\n        \n        # Implement controlled modular addition\n        # Use standard quantum addition circuits with modulo L\n        # This typically involves quantum adders and modular reduction\n        for j in range(n):\n            if (controlled_value >> j) & 1:\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import QFT\n\ndef modular_addition(qc, x, y, a, L, n):\n    \"\"\" Implements y -> (y + ax) mod L \"\"\"\n    for i in range(n):\n        for j in range(n + 1):\n            if (a >> i) & 1:\n                qc.ccx(x[i], y[j], y[(j + (1 << i)) % (n + 1)])\n    \n    # Modulo L enforcement\n    qc.append(QFT(n+1, do_swaps=False).inverse(), y)\n    qc.x(y[n])\n    qc.append(QFT(n+1, do_swaps=False), y)\n    \n    return qc\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x = QuantumRegister(n, name='x')\n    y = QuantumRegister(n + 1, name='y')\n    qc = QuantumCircuit(x, y)\n    \n    # Implement modular addition oracle\n    modular_addition(qc, x, y, a, L, n)\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 3, "result": "WA", "execution_time": "1942 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(n + 1, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # Apply controlled addition for each qubit in x\n    for i in range(n):\n        # Controlled addition of a * 2^i to y\n        for j in range(n + 1):\n            if (a * (1 << i)) & (1 << j):\n                qc.cx(x[i], y[j])\n    \n    # Apply modulo L operation\n    # Since L <= 2^n, we can use a comparison and subtraction approach\n    # This is a simplified approach and may need refinement for specific cases\n    # For a full implementation, additional qubits and gates would be needed\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 4, "result": "WA", "execution_time": "1620 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    # Create quantum registers for x and y\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(n, 'y')\n    \n    # Create quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # We need to perform (y + ax) mod L\n    # We can implement this using controlled additions\n    \n    # For each qubit i in x register\n    for i in range(n):\n        # If the i-th bit of x is 1, we add a*2^i to y (controlled addition)\n        value = (a * (1 << i)) % L  # Calculate the value to add (mod L)\n        \n        # Break down value into binary for controlled additions\n        for j in range(n):\n            if value & (1 << j):\n                qc.cx(x[i], y[j])\n    \n    # The modulo L operation is handled implicitly since:\n    # 1. L <= 2^n (from constraints)\n    # 2. We're already doing (a * 2^i) mod L in our addition\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 5, "result": "WA", "execution_time": "1665 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    # Create quantum registers for x and y\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(n + 1, 'y')  # Note: n+1 qubits for y as per problem\n    \n    # Create quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # For each bit i in x\n    for i in range(n):\n        # For each bit j in y\n        for j in range(n + 1):\n            # Apply controlled addition based on the pattern:\n            # If bit i in x is 1, we add corresponding value to y\n            if (a * (1 << i)) & (1 << j):\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 6, "result": "WA", "execution_time": "1988 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    # Create quantum registers for x and y\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(n + 1, 'y')\n    \n    # Create quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # Apply controlled addition for each qubit in x\n    for i in range(n):\n        # Controlled addition of a * 2^i to y\n        for j in range(n + 1):\n            if (a * (1 << i)) & (1 << j):\n                if j > 0:  # Only apply when j > 0 as per example\n                    qc.cx(x[i], y[j])\n\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 7, "result": "WA", "execution_time": "1801 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    # Create quantum registers for x and y\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(n + 1, 'y')  # n+1 qubits for y register\n    \n    # Create quantum circuit\n    qc = QuantumCircuit(x, y)\n    \n    # Apply controlled addition for each qubit in x\n    for i in range(n):\n        for j in range(n + 1):\n            # Following exactly the condition from the example\n            if (a * (1 << i)) & (1 << j):\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 8, "result": "WA", "execution_time": "1732 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    # Initialize registers\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(n, 'y')  # Note: Problem shows n qubits for y\n    qc = QuantumCircuit(x, y)\n    \n    # Controlled addition of ax mod L to y\n    # The key is to apply controlled-X gates based on the binary representation\n    # of (a * x) mod L\n    \n    # For each control qubit in x\n    for i in range(n):\n        # For each target qubit in y\n        for j in range(n):\n            # The condition from example: if this bit position should flip\n            if (a * (1 << i)) & (1 << j):\n                # Apply controlled-NOT from x[i] to y[j]\n                qc.cx(x[i], y[j])\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 9, "result": "WA", "execution_time": "1753 ms", "memory": "163 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Creates a quantum circuit that performs modular multiplication: |x⟩|y⟩ → |x⟩|y ⊕ (ax mod L)⟩\n    \n    Args:\n        n (int): Number of qubits in each register\n        a (int): Multiplication factor\n        L (int): Modulus\n        \n    Returns:\n        QuantumCircuit: Circuit implementing the modular multiplication\n    \"\"\"\n    # Initialize registers\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(n, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # For each possible value of x\n    for x_val in range(1 << n):\n        # Calculate (a * x_val) mod L\n        result = (a * x_val) % L\n        \n        # For each target qubit in y\n        for j in range(n):\n            # If this bit should be flipped for this x_val\n            if result & (1 << j):\n                # Create control pattern for this x_val\n                for i in range(n):\n                    # Apply X or CX gates based on x_val bits\n                    if x_val & (1 << i):\n                        qc.cx(x[i], y[j])\n                    else:\n                        # If control bit should be 0, add X gates before and after\n                        qc.x(x[i])\n                        qc.cx(x[i], y[j])\n                        qc.x(x[i])\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "A99EBFB8A8CD1", "submission_order": 10, "result": "WA", "execution_time": "1626 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Creates a quantum circuit that performs modular multiplication: |x⟩|y⟩ → |x⟩|y ⊕ (ax mod L)⟩\n    \n    Args:\n        n (int): Number of qubits in each register\n        a (int): Multiplication factor\n        L (int): Modulus\n        \n    Returns:\n        QuantumCircuit: Circuit implementing the modular multiplication\n    \"\"\"\n    # Initialize registers\n    x = QuantumRegister(n, 'x')\n    y = QuantumRegister(n, 'y')\n    qc = QuantumCircuit(x, y)\n    \n    # Create table of all possible values and their modular products\n    for x_val in range(1 << n):\n        result = (a * x_val) % L\n        \n        # For each bit in result\n        for j in range(n):\n            if result & (1 << j):\n                # Create control pattern\n                controls = []\n                neg_controls = []\n                \n                # Determine which qubits should be controlled on 0 vs 1\n                for i in range(n):\n                    if x_val & (1 << i):\n                        controls.append(i)\n                    else:\n                        neg_controls.append(i)\n                \n                # Apply X gates before controlled operation\n                for i in neg_controls:\n                    qc.x(x[i])\n                \n                # Apply multi-controlled X gate\n                if len(controls + neg_controls) > 0:\n                    for control in controls + neg_controls:\n                        qc.cx(x[control], y[j])\n                \n                # Restore X gates after controlled operation\n                for i in neg_controls:\n                    qc.x(x[i])\n    \n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "AC58B559AAF5B", "submission_order": 1, "result": "WA", "execution_time": "1594 ms", "memory": "161 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        for j in range(n+1):\n            if (a >> i) & 1:\n                qc.cx(x[i], y[j])  # CNOTゲートでx[i]に基づいてy[j]に操作を行う\n\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "ADE5FF0F4C260", "submission_order": 1, "result": "RE", "execution_time": "1575 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef add(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n)\n    qc = QuantumCircuit(k)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.p(theta, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef controlled_add(n: int, a: int, control_count: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(control_count)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.mcp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef controlled_oracle_less(bitcount: int, n: int, control_count: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    control = QuantumRegister(control_count)\n    qc = QuantumCircuit(regin, regout, control)\n\n    if n >= 2**bitcount:\n        qc.mcx(control, regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        regin_controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            regin_controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.mcx(control, regin[idx])\n\n        if len(regin_controls) != 0:\n            qc.mcx([*regin_controls, *control], regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef cmodadd(n: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"in(n+1), control, anc1, anc2, anc3\"\"\"\n    regin = QuantumRegister(n + 1)\n    control = QuantumRegister(1)\n    qc = QuantumCircuit(regin, control)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.cx(control, anc_range1)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L - a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.mcx([*control, anc_range1, anc_range2], anc_range3)\n\n    qc.compose(controlled_add(n + 1, a, 1), [*regin, *control], inplace=True)\n    qc.compose(\n        controlled_add(n + 1, -L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n    qc.mcx([anc_range1, anc_range2, *control], anc_range3)\n\n    qc.cx(control, anc_range2)\n    qc.cx(control, regin[-1])\n    qc.mcx([regin[-1], *anc_range2, *control], anc_range3)\n    qc.cx(control, regin[-1])\n    qc.compose(\n        controlled_add(n + 1, L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, 2 ** (n + 1) + 1 - L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n    qc.compose(controlled_oracle_less(n + 1, L, 1), [*regin, *anc_range3,*control], inplace=True)\n\n    qc.cx(control, anc_range2)\n    qc.compose(controlled_oracle_less(n + 1, L, 1), [*regin, *anc_range2,*control], inplace=True)\n\n    qc.compose(controlled_oracle_less(n + 1, L, 1), [*regin, *anc_range1,*control], inplace=True)\n    qc.compose(controlled_oracle_less(n + 1, a, 1), [*regin, *anc_range1,*control], inplace=True)\n    qc.cx(control, anc_range1)\n\n    return qc\n\n\ndef modfma(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    ancs = QuantumRegister(3)\n    qc.add_register(ancs)\n\n    for idx in range(n):\n        add = pow(a, 2**idx, L)\n        qc.compose(cmodadd(n, add, L), [*y, x[idx], *ancs], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "ADE5FF0F4C260", "submission_order": 2, "result": "RE", "execution_time": "1598 ms", "memory": "159 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef add(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n)\n    qc = QuantumCircuit(k)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.p(theta, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef controlled_add(n: int, a: int, control_count: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(control_count)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.mcp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef controlled_oracle_less(bitcount: int, n: int, control_count: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    control = QuantumRegister(control_count)\n    qc = QuantumCircuit(regin, regout, control)\n\n    if n >= 2**bitcount:\n        qc.mcx(control, regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        regin_controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            regin_controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.mcx(control, regin[idx])\n\n        if len(regin_controls) != 0:\n            qc.mcx([*regin_controls, *control], regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.mcx(control, regin[idx])\n\n    return qc\n\n\ndef modadd(n: int, a: int, L: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.x(anc_range1)\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range2], inplace=True)\n    qc.compose(oracle_less(n + 1, L - a), [*regin, *anc_range1], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.compose(add(n + 1, a), inplace=True)\n    qc.compose(controlled_add(n + 1, -L, 1), [*regin, *anc_range3], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.x(anc_range2)\n    qc.x(regin[-1])\n    qc.ccx(regin[-1], anc_range2, anc_range3)\n    qc.x(regin[-1])\n    qc.compose(controlled_add(n + 1, L, 1), [*regin, *anc_range3], inplace=True)\n\n    qc.compose(\n        oracle_less(n + 1, 2 ** (n + 1) + 1 - L), [*regin, *anc_range3], inplace=True\n    )\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range3], inplace=True)\n\n    qc.x(anc_range2)\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range2], inplace=True)\n\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range1], inplace=True)\n    qc.compose(oracle_less(n + 1, a), [*regin, *anc_range1], inplace=True)\n    qc.x(anc_range1)\n\n    return qc\n\n\ndef cmodadd(n: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"in(n+1), control, anc1, anc2, anc3\"\"\"\n    regin = QuantumRegister(n + 1)\n    control = QuantumRegister(1)\n    qc = QuantumCircuit(regin, control)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.cx(control, anc_range1)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L - a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.mcx([*control, anc_range1, anc_range2], anc_range3)\n\n    qc.compose(controlled_add(n + 1, a, 1), [*regin, *control], inplace=True)\n    qc.compose(\n        controlled_add(n + 1, -L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n    qc.mcx([anc_range1, anc_range2, *control], anc_range3)\n\n    qc.cx(control, anc_range2)\n    qc.cx(control, regin[-1])\n    qc.mcx([regin[-1], *anc_range2, *control], anc_range3)\n    qc.cx(control, regin[-1])\n    qc.compose(\n        controlled_add(n + 1, L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, 2 ** (n + 1) + 1 - L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n\n    qc.cx(control, anc_range2)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.cx(control, anc_range1)\n\n    return qc\n\n\ndef modfma(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    ancs = QuantumRegister(3)\n    qc.add_register(ancs)\n\n    for idx in range(n):\n        add = pow(a, 2**idx, L)\n        qc.compose(cmodadd(n, add, L), [*y, x[idx], *ancs], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "ADE5FF0F4C260", "submission_order": 3, "result": "RE", "execution_time": "1527 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef add(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n)\n    qc = QuantumCircuit(k)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.p(theta, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef controlled_add(n: int, a: int, control_count: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(control_count)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.mcp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef controlled_oracle_less(bitcount: int, n: int, control_count: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    control = QuantumRegister(control_count)\n    qc = QuantumCircuit(regin, regout, control)\n\n    if n >= 2**bitcount:\n        qc.mcx(control, regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        regin_controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            regin_controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.mcx(control, regin[idx])\n\n        if len(regin_controls) != 0:\n            qc.mcx([*regin_controls, *control], regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.mcx(control, regin[idx])\n\n    return qc\n\n\ndef modadd(n: int, a: int, L: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.x(anc_range1)\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range2], inplace=True)\n    qc.compose(oracle_less(n + 1, L - a), [*regin, *anc_range1], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.compose(add(n + 1, a), inplace=True)\n    qc.compose(controlled_add(n + 1, -L, 1), [*regin, *anc_range3], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.x(anc_range2)\n    qc.x(regin[-1])\n    qc.ccx(regin[-1], anc_range2, anc_range3)\n    qc.x(regin[-1])\n    qc.compose(controlled_add(n + 1, L, 1), [*regin, *anc_range3], inplace=True)\n\n    qc.compose(\n        oracle_less(n + 1, 2 ** (n + 1) + 1 - L), [*regin, *anc_range3], inplace=True\n    )\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range3], inplace=True)\n\n    qc.x(anc_range2)\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range2], inplace=True)\n\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range1], inplace=True)\n    qc.compose(oracle_less(n + 1, a), [*regin, *anc_range1], inplace=True)\n    qc.x(anc_range1)\n\n    return qc\n\n\ndef cmodadd(n: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"in(n+1), control, anc1, anc2, anc3\"\"\"\n    regin = QuantumRegister(n + 1)\n    control = QuantumRegister(1)\n    qc = QuantumCircuit(regin, control)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.cx(control, anc_range1)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L - a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.mcx([*control, anc_range1, anc_range2], anc_range3)\n\n    qc.compose(controlled_add(n + 1, a, 1), [*regin, *control], inplace=True)\n    qc.compose(\n        controlled_add(n + 1, -L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n    qc.mcx([anc_range1, anc_range2, *control], anc_range3)\n\n    qc.cx(control, anc_range2)\n    qc.cx(control, regin[-1])\n    qc.mcx([regin[-1], *anc_range2, *control], anc_range3)\n    qc.cx(control, regin[-1])\n    qc.compose(\n        controlled_add(n + 1, L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, 2 ** (n + 1) + 1 - L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n\n    qc.cx(control, anc_range2)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.cx(control, anc_range1)\n\n    return qc\n\n\ndef modfma(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    ancs = QuantumRegister(3)\n    qc.add_register(ancs)\n\n    for idx in range(n):\n        add = a * (2**idx) % L\n        qc.compose(cmodadd(n, add, L), [*y, x[idx], *ancs], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "ADE5FF0F4C260", "submission_order": 4, "result": "AC", "execution_time": "2773 ms", "memory": "167 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef add(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n)\n    qc = QuantumCircuit(k)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.p(theta, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef controlled_add(n: int, a: int, control_count: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(control_count)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.mcp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef controlled_oracle_less(bitcount: int, n: int, control_count: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    control = QuantumRegister(control_count)\n    qc = QuantumCircuit(regin, regout, control)\n\n    if n >= 2**bitcount:\n        qc.mcx(control, regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        regin_controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            regin_controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.mcx(control, regin[idx])\n\n        if len(regin_controls) != 0:\n            qc.mcx([*regin_controls, *control], regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.mcx(control, regin[idx])\n\n    return qc\n\n\ndef modadd(n: int, a: int, L: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.x(anc_range1)\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range2], inplace=True)\n    qc.compose(oracle_less(n + 1, L - a), [*regin, *anc_range1], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.compose(add(n + 1, a), inplace=True)\n    qc.compose(controlled_add(n + 1, -L, 1), [*regin, *anc_range3], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.x(anc_range2)\n    qc.x(regin[-1])\n    qc.ccx(regin[-1], anc_range2, anc_range3)\n    qc.x(regin[-1])\n    qc.compose(controlled_add(n + 1, L, 1), [*regin, *anc_range3], inplace=True)\n\n    qc.compose(\n        oracle_less(n + 1, 2 ** (n + 1) + 1 - L), [*regin, *anc_range3], inplace=True\n    )\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range3], inplace=True)\n\n    qc.x(anc_range2)\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range2], inplace=True)\n\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range1], inplace=True)\n    qc.compose(oracle_less(n + 1, a), [*regin, *anc_range1], inplace=True)\n    qc.x(anc_range1)\n\n    return qc\n\n\ndef cmodadd(n: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"in(n+1), control, anc1, anc2, anc3\"\"\"\n    regin = QuantumRegister(n + 1)\n    control = QuantumRegister(1)\n    qc = QuantumCircuit(regin, control)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.cx(control, anc_range1)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L - a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.mcx([*control, anc_range1, anc_range2], anc_range3)\n\n    qc.compose(controlled_add(n + 1, a, 1), [*regin, *control], inplace=True)\n    qc.compose(\n        controlled_add(n + 1, -L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n    qc.mcx([anc_range1, anc_range2, *control], anc_range3)\n\n    qc.cx(control, anc_range2)\n    qc.cx(control, regin[-1])\n    qc.mcx([regin[-1], *anc_range2, *control], anc_range3)\n    qc.cx(control, regin[-1])\n    qc.compose(\n        controlled_add(n + 1, L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, 2 ** (n + 1) + 1 - L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n\n    qc.cx(control, anc_range2)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.cx(control, anc_range1)\n\n    return qc\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    ancs = QuantumRegister(3)\n    qc.add_register(ancs)\n\n    for idx in range(n):\n        add = a * (2**idx) % L\n        qc.compose(cmodadd(n, add, L), [*y, x[idx], *ancs], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "ADF02875A7997", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "173 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L).control(1),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n+1,2**n-L+a), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(add(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(add(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    return qc\n\ndef add(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(-2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "ADF02875A7997", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "172 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L).control(1),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n+1,2**n-L+a), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(add(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(add(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    return qc\n\ndef add(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(-2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n'''"}
{"problem": "QPC004_C3", "user": "ADF02875A7997", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "172 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L).control(1),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n+1,2**n-L+a), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(add(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(n)), inplace=True)\n    qc.compose(shift(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(shift(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(iqft(n),qubits = list(range(n)), inplace=True)\n    return qc\n\ndef add(n,a):\n    qc = QuantumCircuit(n)\n    qc.compose(qft(n), inplace=True)\n    qc.compose(shift(n,a), inplace=True)\n    qc.compose(iqft(n), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef iqft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(-2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A39B0C341BDED", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import QFT\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    # Create quantum registers\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Apply QFT to input register\n    qft = QFT(n, do_swaps=False)\n    qc.append(qft, x[:])\n    \n    # Step 2: Phase rotations based on modular multiplication\n    for i in range(n):\n        for j in range(i + 1):\n            # Calculate phase for controlled rotation\n            phase = (2 * (a * 2**(i-j)) % L) / L\n            # Add controlled phase rotation\n            qc.cp(2 * pi * phase, x[j], y[i])\n    \n    # Step 3: Apply inverse QFT\n    qft_dagger = QFT(n, do_swaps=False).inverse()\n    qc.append(qft_dagger, x[:])\n    \n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A39B0C341BDED", "submission_order": 2, "result": "WA", "execution_time": "1784 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi\n\ndef qft(qc: QuantumCircuit, q: QuantumRegister, n: int):\n    \"\"\"Implement QFT from scratch\"\"\"\n    for i in range(n):\n        qc.h(q[i])\n        for j in range(i+1, n):\n            qc.cp(pi/2**(j-i), q[j], q[i])\n\ndef inverse_qft(qc: QuantumCircuit, q: QuantumRegister, n: int):\n    \"\"\"Implement inverse QFT from scratch\"\"\"\n    for i in range(n-1, -1, -1):\n        for j in range(n-1, i, -1):\n            qc.cp(-pi/2**(j-i), q[j], q[i])\n        qc.h(q[i])\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    # Create quantum registers\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Apply custom QFT to input register\n    qft(qc, x, n)\n    \n    # Step 2: Phase rotations based on modular multiplication\n    for i in range(n):\n        for j in range(i + 1):\n            # Calculate phase for controlled rotation\n            phase = (2 * (a * 2**(i-j)) % L) / L\n            qc.cp(2 * pi * phase, x[j], y[i])\n    \n    # Step 3: Apply custom inverse QFT\n    inverse_qft(qc, x, n)\n    \n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A39B0C341BDED", "submission_order": 3, "result": "RE", "execution_time": "1764 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef qft(n: int, inverse=False):\n    \"\"\"Manually implement the Quantum Fourier Transform (QFT)\"\"\"\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(-np.pi / 2**(k - j), k, j)  # Controlled phase gate\n    if inverse:\n        qc = qc.inverse()  # Take inverse if needed\n    return qc\n\ndef modular_addition(n: int, a: int):\n    \"\"\"Implement modular addition using QFT and controlled phase gates.\"\"\"\n    qc = QuantumCircuit(n)\n    \n    # Apply QFT\n    qc.append(qft(n), range(n))\n\n    # Apply phase shifts to encode addition\n    for i in range(n):\n        if (a >> i) & 1:  # Check if bit i of 'a' is set\n            qc.p(np.pi / 2**(n - i - 1), i)\n    \n    # Apply inverse QFT\n    qc.append(qft(n, inverse=True), range(n))\n    \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"Controlled constant addition circuit.\"\"\"\n    k_reg = QuantumRegister(n, name='k')\n    c_reg = QuantumRegister(1, name='c')  # Control qubit\n    qc = QuantumCircuit(k_reg, c_reg)\n    \n    # Controlled modular addition: Apply only if control qubit is 1\n    controlled_add = modular_addition(n, a).control(1)\n    \n    qc.append(controlled_add, [c_reg[0]] + k_reg[:])\n    \n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A39B0C341BDED", "submission_order": 4, "result": "RE", "execution_time": "1656 ms", "memory": "157 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef manual_qft(n):\n    \"\"\"Constructs the Quantum Fourier Transform (QFT) without using the Qiskit QFT library.\"\"\"\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        qc.h(j)\n        for k in range(j + 1, n):\n            qc.cp(np.pi / 2**(k - j), k, j)\n    return qc\n\ndef manual_iqft(n):\n    \"\"\"Constructs the Inverse Quantum Fourier Transform (IQFT) manually.\"\"\"\n    return manual_qft(n).inverse()\n\ndef controlled_modular_addition(n, a):\n    \"\"\"Implements controlled modular addition using QFT and controlled phase shifts.\"\"\"\n    qc = QuantumCircuit(n + 1)  # +1 for the control qubit\n\n    # Apply QFT to the lower n qubits\n    qft_circuit = manual_qft(n)\n    qc.append(qft_circuit, range(n))\n\n    # Apply controlled phase shifts based on 'a'\n    for i in range(n):\n        if (a >> i) & 1:  # Check if bit i of 'a' is set\n            qc.cp(np.pi / 2**(n - i - 1), n, i)  # Controlled phase shift by control qubit\n\n    # Apply inverse QFT\n    iqft_circuit = manual_iqft(n)\n    qc.append(iqft_circuit, range(n))\n\n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"Implements the Controlled Constant Addition circuit while following constraints.\"\"\"\n    k_reg = QuantumRegister(n, name='k')  # Register for 'k'\n    c_reg = QuantumRegister(1, name='c')  # Control qubit\n    qc = QuantumCircuit(k_reg, c_reg)\n\n    # Controlled addition: Applied only if c = 1\n    controlled_add = controlled_modular_addition(n, a).to_gate(label=\"C-ADD(a)\").control(1)\n    qc.append(controlled_add, [c_reg[0]] + k_reg[:])\n\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A39B0C341BDED", "submission_order": 5, "result": "RE", "execution_time": "2016 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef controlled_modular_addition(n, a):\n    \"\"\"Implements controlled modular addition using bitwise operations.\"\"\"\n    qc = QuantumCircuit(n + 1)  # Extra qubit for control\n\n    for i in range(n):\n        if (a >> i) & 1:  # If the i-th bit of 'a' is 1\n            qc.cx(n, i)  # Controlled-X: If control is 1, flip bit i of 'k'\n    \n    return qc\n\ndef solve(n: int, a: int) -> QuantumCircuit:\n    \"\"\"Constructs an optimized controlled modular addition circuit.\"\"\"\n    k_reg = QuantumRegister(n, name='k')  # Register for k\n    c_reg = QuantumRegister(1, name='c')  # Control qubit\n    qc = QuantumCircuit(k_reg, c_reg)\n\n    # Apply controlled modular addition (bitwise controlled-X operations)\n    controlled_add = controlled_modular_addition(n, a).to_gate(label=\"C-ADD(a)\").control(1)\n    \n    qc.append(controlled_add, [c_reg[0]] + k_reg[:])\n\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A49D000568755", "submission_order": 1, "result": "AC", "execution_time": "2455 ms", "memory": "170 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\nimport numpy as np\nimport math\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * math.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef add(n: int, a: int) -> QuantumCircuit:\n    k = QuantumRegister(n)\n    qc = QuantumCircuit(k)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.p(theta, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef controlled_add(n: int, a: int, control_count: int) -> QuantumCircuit:\n    k, c = QuantumRegister(n), QuantumRegister(control_count)\n    qc = QuantumCircuit(k, c)\n    # Write your code here:\n\n    qc.compose(qft(n), inplace=True)\n\n    for idx in range(n):\n        theta = 2 * a * math.pi * (2**idx) / (2**n)\n        qc.mcp(theta, c, k[idx])\n\n    qc.compose(qft(n).inverse(), inplace=True)\n\n    return qc\n\n\ndef oracle_less(bitcount: int, n: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    qc = QuantumCircuit(regin, regout)\n\n    if n >= 2**bitcount:\n        qc.x(regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.x(regin[idx])\n\n        if len(controls) != 0:\n            qc.mcx(controls, regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.x(regin[idx])\n\n    return qc\n\n\ndef controlled_oracle_less(bitcount: int, n: int, control_count: int) -> QuantumCircuit:\n    regin, regout = QuantumRegister(bitcount), QuantumRegister(1)\n    control = QuantumRegister(control_count)\n    qc = QuantumCircuit(regin, regout, control)\n\n    if n >= 2**bitcount:\n        qc.mcx(control, regout)\n        return qc\n\n    bitrep = bin(n)[2:].zfill(bitcount)[::-1]\n    masks = []\n\n    for idx in range(bitcount):\n        if bitrep[idx] == \"1\":\n            mask = (\"0\" + bitrep[idx + 1 :]).rjust(bitcount, \"*\")\n            masks.append(mask)\n\n    flipped = [False] * bitcount\n    for mask in masks:\n        regin_controls = []\n        for idx in range(bitcount):\n            if mask[idx] == \"*\":\n                continue\n\n            regin_controls.append(regin[idx])\n            if (mask[idx] == \"0\") != (flipped[idx]):\n                flipped[idx] = not flipped[idx]\n                qc.mcx(control, regin[idx])\n\n        if len(regin_controls) != 0:\n            qc.mcx([*regin_controls, *control], regout)\n\n    for idx in range(bitcount):\n        if flipped[idx]:\n            qc.mcx(control, regin[idx])\n\n    return qc\n\n\ndef modadd(n: int, a: int, L: int) -> QuantumCircuit:\n    regin = QuantumRegister(n + 1)\n    qc = QuantumCircuit(regin)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.x(anc_range1)\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range2], inplace=True)\n    qc.compose(oracle_less(n + 1, L - a), [*regin, *anc_range1], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.compose(add(n + 1, a), inplace=True)\n    qc.compose(controlled_add(n + 1, -L, 1), [*regin, *anc_range3], inplace=True)\n    qc.ccx(anc_range1, anc_range2, anc_range3)\n\n    qc.x(anc_range2)\n    qc.x(regin[-1])\n    qc.ccx(regin[-1], anc_range2, anc_range3)\n    qc.x(regin[-1])\n    qc.compose(controlled_add(n + 1, L, 1), [*regin, *anc_range3], inplace=True)\n\n    qc.compose(\n        oracle_less(n + 1, 2 ** (n + 1) + 1 - L), [*regin, *anc_range3], inplace=True\n    )\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range3], inplace=True)\n\n    qc.x(anc_range2)\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range2], inplace=True)\n\n    qc.compose(oracle_less(n + 1, L), [*regin, *anc_range1], inplace=True)\n    qc.compose(oracle_less(n + 1, a), [*regin, *anc_range1], inplace=True)\n    qc.x(anc_range1)\n\n    return qc\n\n\ndef cmodadd(n: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"in(n+1), control, anc1, anc2, anc3\"\"\"\n    regin = QuantumRegister(n + 1)\n    control = QuantumRegister(1)\n    qc = QuantumCircuit(regin, control)\n    # Write your code here:\n\n    anc_range1 = QuantumRegister(1)\n    anc_range2 = QuantumRegister(1)\n    anc_range3 = QuantumRegister(1)\n    qc.add_register(anc_range1)\n    qc.add_register(anc_range2)\n    qc.add_register(anc_range3)\n\n    qc.cx(control, anc_range1)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L - a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.mcx([*control, anc_range1, anc_range2], anc_range3)\n\n    qc.compose(controlled_add(n + 1, a, 1), [*regin, *control], inplace=True)\n    qc.compose(\n        controlled_add(n + 1, -L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n    qc.mcx([anc_range1, anc_range2, *control], anc_range3)\n\n    qc.cx(control, anc_range2)\n    qc.cx(control, regin[-1])\n    qc.mcx([regin[-1], *anc_range2, *control], anc_range3)\n    qc.cx(control, regin[-1])\n    qc.compose(\n        controlled_add(n + 1, L, 2), [*regin, *anc_range3, *control], inplace=True\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, 2 ** (n + 1) + 1 - L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range3, *control],\n        inplace=True,\n    )\n\n    qc.cx(control, anc_range2)\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range2, *control],\n        inplace=True,\n    )\n\n    qc.compose(\n        controlled_oracle_less(n + 1, L, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.compose(\n        controlled_oracle_less(n + 1, a, 1),\n        [*regin, *anc_range1, *control],\n        inplace=True,\n    )\n    qc.cx(control, anc_range1)\n\n    return qc\n\n\ndef cmodfma(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    ancs = QuantumRegister(3)\n    qc.add_register(ancs)\n\n    for idx in range(n):\n        add = a * (2**idx) % L\n        qc.compose(cmodadd(n, add, L), [*y, x[idx], *ancs], inplace=True)\n\n    return qc\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n\n    ancs = QuantumRegister(3)\n    qc.add_register(ancs)\n\n    qc.compose(cmodfma(n, a, L), inplace=True)\n\n    for idx in range(n):\n        qc.swap(x[idx], y[idx])\n\n    qc.compose(cmodfma(n, -pow(a, -1, L), L), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A841677C41D28", "submission_order": 1, "result": "WA", "execution_time": "1933 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x = QuantumRegister(n)  # Register for input x\n    y = QuantumRegister(n + 1)  # Register for output ax mod L\n    qc = QuantumCircuit(x, y)\n\n    # We will implement the multiplication by a and then take mod L\n    # We will use a series of controlled additions to achieve this.\n\n    # We need to add a * x to the output register\n    for i in range(n):\n        if (a >> i) & 1:  # Check if the i-th bit of a is set\n            # We will add x to the output register controlled by the i-th qubit of x\n            for j in range(n + 1):\n                # Controlled addition of x to y\n                qc.cx(x[i], y[j])  # Controlled-X gate to add x to y\n\n    # Now we need to apply the modulo operation\n    # We will use a series of Toffoli gates to implement the modulo operation\n    # This is a simplified version and may not be the most efficient way to implement mod L\n    # but it will work for small values of n and L.\n\n    # We will use a classical approach to implement the modulo operation\n    # by checking if the value exceeds L and then subtracting L if necessary.\n    # This is a naive implementation and may need optimization for larger values.\n\n    # For simplicity, we will assume L is a power of 2, which is true for the given constraints.\n    # We will use the last qubit of y to store the carry for the modulo operation.\n\n    # Example: if L = 2^n, we can simply ignore the overflow bits.\n    # This is a placeholder for the actual modulo operation.\n    # In practice, you would need to implement a more complex circuit to handle arbitrary L.\n\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A8FFDD8E2F3A2", "submission_order": 1, "result": "TLE", "execution_time": "3000 ms", "memory": "178 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.cx(i,n+i)\n        qc.cx(n+i,i)\n        qc.cx(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L).control(1),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(add(n+1,2**n-L+a), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(add(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(n)), inplace=True)\n    qc.compose(shift(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(shift(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(iqft(n),qubits = list(range(n)), inplace=True)\n    return qc\n\ndef add(n,a):\n    qc = QuantumCircuit(n)\n    qc.compose(qft(n), inplace=True)\n    qc.compose(shift(n,a), inplace=True)\n    qc.compose(iqft(n), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef iqft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(-2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A8FFDD8E2F3A2", "submission_order": 2, "result": "TLE", "execution_time": "3000 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.cx(i,n+i)\n        qc.cx(n+i,i)\n        qc.cx(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L).control(1),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(iqft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a), inplace=True)\n    qc.compose(iqft(n+1), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1), inplace=True)\n    qc.compose(shift(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(n)), inplace=True)\n    qc.compose(shift(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(shift(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(iqft(n),qubits = list(range(n)), inplace=True)\n    return qc\n\ndef add(n,a):\n    qc = QuantumCircuit(n)\n    qc.compose(qft(n), inplace=True)\n    qc.compose(shift(n,a), inplace=True)\n    qc.compose(iqft(n), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef iqft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(-2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A8FFDD8E2F3A2", "submission_order": 3, "result": "TLE", "execution_time": "3000 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.cx(i,n+i)\n        qc.cx(n+i,i)\n        qc.cx(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L).control(1),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a), inplace=True)\n    qc.compose(qft(n+1).inverse(), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1), inplace=True)\n    qc.compose(shift(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(n)), inplace=True)\n    qc.compose(shift(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(shift(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(qft(n).inverse(),qubits = list(range(n)), inplace=True)\n    return qc\n\ndef add(n,a):\n    qc = QuantumCircuit(n)\n    qc.compose(qft(n), inplace=True)\n    qc.compose(shift(n,a), inplace=True)\n    qc.compose(qft(n).inverse(), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef iqft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(-2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A8FFDD8E2F3A2", "submission_order": 4, "result": "TLE", "execution_time": "3000 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.cx(i,n+i)\n        qc.cx(n+i,i)\n        qc.cx(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L).control(1),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a), inplace=True)\n    qc.compose(qft(n+1).inverse(), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1), inplace=True)\n    qc.compose(shift(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(n)), inplace=True)\n    qc.compose(shift(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(shift(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(qft(n).inverse(),qubits = list(range(n)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A8FFDD8E2F3A2", "submission_order": 5, "result": "TLE", "execution_time": "3000 ms", "memory": "182 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.swap(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L).control(1),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a), inplace=True)\n    qc.compose(qft(n+1).inverse(), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1), inplace=True)\n    qc.compose(shift(n+1,a), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(n)), inplace=True)\n    qc.compose(shift(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(shift(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(qft(n).inverse(),qubits = list(range(n)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A8FFDD8E2F3A2", "submission_order": 6, "result": "WA", "execution_time": "2534 ms", "memory": "165 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\n\ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        b = (a*2**i)%L\n        qc.compose(shift(n+1,2**n-L+b), inplace=True)\n        qc.compose(qft(n+1).inverse(), inplace=True)\n        qc.compose(pack(n,2**n-L+b,2**n+b), inplace=True)\n        qc.compose(qft(n+1), inplace=True)\n        qc.compose(shift(n+1,b), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.swap(i,n+i)\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        b = ((L-a_inv)*2**i)%L\n        qc.compose(shift(n+1,2**n-L+b), inplace=True)\n        qc.compose(qft(n+1).inverse(), inplace=True)\n        qc.compose(pack(n,2**n-L+b,2**n+b), inplace=True)\n        qc.compose(qft(n+1), inplace=True)\n        qc.compose(shift(n+1,b), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(n)), inplace=True)\n    qc.compose(shift(n,-t).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(shift(n,-s).control(1),qubits = [n]+list(range(n)), inplace=True)\n    qc.x(n)\n    qc.compose(qft(n).inverse(),qubits = list(range(n)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C4", "user": "A8FFDD8E2F3A2", "submission_order": 7, "result": "AC", "execution_time": "2847 ms", "memory": "164 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(math.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n \n \ndef crot(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.cp(theta, n, i)\n \n    return qc\n \n \ndef cadd(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n \n    qc.compose(qft(n), qubits=range(n), inplace=True)\n    qc.compose(crot(n, a), qubits=range(n + 1), inplace=True)\n    qc.compose(qft(n).inverse(), qubits=range(n), inplace=True)\n \n    return qc\n \n \ndef ccrot(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n \n    for i in range(n):\n        theta = 2 * math.pi * a * 2**i / 2**n\n        qc.mcp(theta, [n, n + 1], i)\n \n    return qc\n \n \ndef ccadd(n: int, a: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n \n    qc.compose(qft(n), qubits=range(n), inplace=True)\n    qc.compose(ccrot(n, a), qubits=range(n + 2), inplace=True)\n    qc.compose(qft(n).inverse(), qubits=range(n), inplace=True)\n \n    return qc\n \n \ndef cpack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n \n    qc.compose(ccadd(n, 2 ** (n + 1) - t), qubits=range(n + 2), inplace=True)\n \n    qc.x(n)\n    qc.compose(ccadd(n, -s), qubits=range(n + 2), inplace=True)\n    qc.x(n)\n \n    return qc\n \n \ndef add_ax_mod(n: int, L: int, a: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n \n    for i in range(n):\n        b = (2**i * a) % L\n        targets = [*y, x[i]]\n        qc.compose(cadd(n + 1, 2**n - L), qubits=targets, inplace=True)\n        qc.compose(cadd(n + 1, b), qubits=targets, inplace=True)\n        qc.compose(cpack(n, 2**n - L + b, 2**n + b), qubits=targets, inplace=True)\n        qc.compose(cadd(n + 1, b), qubits=targets, inplace=True)\n \n    return qc\n \n \ndef inv_mod(a: int, L: int) -> int:\n    def extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n        if b == 0:\n            return a, 1, 0\n \n        gcd, x1, y1 = extended_euclidean(b, a % b)\n \n        x = y1\n        y = x1 - (a // b) * y1\n \n        return gcd, x, y\n \n    _, x, _ = extended_euclidean(a, L)\n \n    return x % L\n \n \ndef solve(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n \n    qc.compose(add_ax_mod(n, L, a), qubits=range(2 * n + 1), inplace=True)\n \n    for i in range(n):\n        qc.swap(x[i], y[i])\n \n    b = -inv_mod(a, L) % L\n    qc.compose(add_ax_mod(n, L, b), qubits=range(2 * n + 1), inplace=True)\n \n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A047671A4EB2D", "submission_order": 1, "result": "WA", "execution_time": "1684 ms", "memory": "160 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Create superposition on the first n qubits\n    for i in range(n):\n        qc.h(x[i])  # Apply Hadamard gate to each qubit in the first register\n\n    # Step 2: Compute a^k mod L for each k in the superposition\n    # We will use controlled operations to achieve this\n    for k in range(2**n):\n        # Calculate a^k mod L\n        mod_result = pow(a, k, L)\n        \n        # Convert mod_result to binary and store in the second register\n        for j in range(2 * m + 1):\n            if (mod_result >> j) & 1:\n                qc.x(y[j])  # Apply X gate to set the corresponding bit\n\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A047671A4EB2D", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import QFT\nimport math\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    \n    # Apply Hadamard gates on the first n qubits\n    for i in range(n):\n        qc.h(x[i])\n    \n    # Apply controlled phase gates based on the value of k\n    for k in range(2**n):\n        binary_k = format(k, '0'+str(n)+'b')  # Convert k to binary string\n        for i in range(n):\n            if binary_k[i] == '0':\n                qc.x(x[i])\n        phase = (a**k) % L\n        binary_phase = format(phase, '0'+str(2*m+1)+'b')  # Convert phase to binary string\n        for i in range(2*m+1):\n            if binary_phase[i] == '1':\n                qc.cp(2*math.pi / (2**m), x, y[i])\n        for i in range(n):\n            if binary_k[i] == '0':\n                qc.x(x[i])\n    \n    # Apply inverse QFT on the first n qubits\n    qft_dagger = QFT(n, inverse=True)\n    qc.append(qft_dagger, x)\n    \n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A047671A4EB2D", "submission_order": 3, "result": "AC", "execution_time": "2076 ms", "memory": "164 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Create |0>_n |0>_(2m+1)  →  (1/√(2^n)) Σ_k |k> |a^k mod L>\n    Registers are in little-endian order.\n    \"\"\"\n    x = QuantumRegister(n, 'x')               # exponent register\n    y = QuantumRegister(2 * m + 1, 'y')       # result register  (enough qubits for L)\n    qc = QuantumCircuit(x, y)\n\n    # 1) Prepare uniform superposition on |x>\n    for i in range(n):\n        qc.h(x[i])                            # |0…0> → (1/√2^n) Σ_k |k>\n\n    # helper: multi-controlled X with an arbitrary number of controls\n    def cX(ctrls, tgt):\n        if len(ctrls) == 0:\n            qc.x(tgt)\n        elif len(ctrls) == 1:\n            qc.cx(ctrls[0], tgt)\n        else:\n            qc.mcx(ctrls, tgt)                # built-in multi-controlled X\n\n    # 2) Encode  a^k  (mod L)  into |y>  for every computational basis state |k>\n    N = 1 << n                                # 2^n\n    y_bits = 2 * m + 1                        # number of qubits in y\n    for k in range(N):\n        value = pow(a, k, L)                  # classical a^k  mod L\n        if value == 0:\n            continue                          # all target bits stay 0\n        # list of control qubits (all qubits of register x)\n        ctrls = [x[i] for i in range(n)]\n        # temporarily flip controls whose bit in k is 0  (so all controls become |1>)\n        zeros = [i for i in range(n) if ((k >> i) & 1) == 0]\n        for i in zeros:\n            qc.x(x[i])\n\n        # for every 1-bit in 'value' flip corresponding qubit in y\n        for bit in range(y_bits):\n            if (value >> bit) & 1:\n                cX(ctrls, y[bit])\n\n        # undo the temporary flips\n        for i in zeros:\n            qc.x(x[i])\n\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A1138001D8D93", "submission_order": 1, "result": "RE", "execution_time": "1844 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    multipliers = doubling_powers(n,a,L)\n    for i in range(n):\n        qc.compose(multiply_mod(m,a,L).control(1),qubits = [i] + list(range(n,n+2*m+1)),inplace=True)\n    return qc\n\ndef doubling_powers(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    for i in range(1,n):\n        result.append(result[-1]**2%L)\n    return result\n\ndef multiply_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.swap(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a).control(1), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(shift(n+1,a).control(1), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(1,n+1)), inplace=True)\n    qc.compose(shift(n,-t).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(shift(n,-s).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(qft(n).inverse(),qubits = list(range(1,n+1)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A1138001D8D93", "submission_order": 2, "result": "WA", "execution_time": "2240 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    multipliers = doubling_powers(n,a,L)\n    for i in range(n):\n        qc.compose(multiply_mod(m,a,L).control(1),qubits = [i] + list(range(n,n+2*m+1)),inplace=True)\n    return qc\n\ndef doubling_powers(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    for i in range(1,n):\n        result.append(result[-1]**2%L)\n    return result\n\ndef multiply_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.swap(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a).control(1), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(shift(n+1,a).control(1), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(1,n+1)), inplace=True)\n    qc.compose(shift(n,-t).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(shift(n,-s).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(qft(n).inverse(),qubits = list(range(1,n+1)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A1138001D8D93", "submission_order": 3, "result": "WA", "execution_time": "4744 ms", "memory": "196 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    multipliers = doubling_powers(n,a,L)\n    for i in range(n):\n        qc.compose(multiply_mod(m,multipliers[i],L).control(1),qubits = [i] + list(range(n,n+2*m+1)),inplace=True)\n    return qc\n\ndef doubling_powers(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    for i in range(1,n):\n        result.append(result[-1]**2%L)\n    return result\n\ndef multiply_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.swap(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a).control(1), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(shift(n+1,a).control(1), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(1,n+1)), inplace=True)\n    qc.compose(shift(n,-t).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(shift(n,-s).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(qft(n).inverse(),qubits = list(range(1,n+1)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A1138001D8D93", "submission_order": 4, "result": "RE", "execution_time": "2267 ms", "memory": "158 MiB", "code": "'''python\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.x(n)\n    multipliers = doubling_powers(n,a,L)\n    for i in range(n):\n        qc.compose(multiply_mod(m,multipliers[i],L).control(1),qubits = [i] + list(range(n,n+2*m+1)),inplace=True)\n    return qc\n\ndef doubling_powers(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    for i in range(1,n):\n        result.append(result[-1]**2%L)\n    return result\n\ndef multiply_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.swap(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a).control(1), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(shift(n+1,a).control(1), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(1,n+1)), inplace=True)\n    qc.compose(shift(n,-t).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(shift(n,-s).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(qft(n).inverse(),qubits = list(range(1,n+1)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A1138001D8D93", "submission_order": 5, "result": "TLE", "execution_time": "10000 ms", "memory": "228 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.x(n)\n    multipliers = doubling_powers(n,a,L)\n    for i in range(n):\n        qc.compose(multiply_mod(m,multipliers[i],L).control(1),qubits = [i] + list(range(n,n+2*m+1)),inplace=True)\n    return qc\n\ndef doubling_powers(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    for i in range(1,n):\n        result.append(result[-1]**2%L)\n    return result\n\ndef multiply_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.swap(i,n+i)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(n + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n,2*n+1)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L),qubits = [i]+list(range(n,2*n+1)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n,2*n+1)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a).control(1), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1),qubits =  list(range(1,n+2)), inplace=True)\n    qc.compose(shift(n+1,a).control(1), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 2)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(1,n+1)), inplace=True)\n    qc.compose(shift(n,-t).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(shift(n,-s).control(2),qubits = [0,n+1]+list(range(1,n+1)), inplace=True)\n    qc.x(n+1)\n    qc.compose(qft(n).inverse(),qubits = list(range(1,n+1)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A1138001D8D93", "submission_order": 6, "result": "AC", "execution_time": "8552 ms", "memory": "202 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(i)\n    qc.x(n)\n    multipliers = doubling_powers(n,a,L)\n    for i in range(n):\n        qc.compose(multiply_mod(m,multipliers[i],L),qubits = [i] + list(range(n,n+2*m+1)),inplace=True)\n    return qc\n\ndef doubling_powers(n: int, a: int, L: int) -> list[int]:\n    result: list[int] = []\n    # Write your code here:\n    result.append(a)\n    for i in range(1,n):\n        result.append(result[-1]**2%L)\n    return result\n\ndef multiply_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2*n+2)\n    # Write your code here:\n    qc.compose(add_multi_mod(n,a,L),inplace=True)\n    gcd,x,y = extended_euclidean(a,L)\n    a_inv = x % L\n    #print(a_inv)\n    for i in range(n):\n        qc.cswap(0,i+1,n+i+1)\n    qc.compose(add_multi_mod(n,L-a_inv,L),inplace=True)\n    return qc\n\ndef extended_euclidean(a: int, b: int) -> tuple[int, int, int]:\n    # when b == 0:\n    if b == 0:\n        return a, 1, 0\n \n    # recursive step\n    gcd, x1, y1 = extended_euclidean(b, a % b)\n \n    # update x and y\n    x = y1\n    y = x1 - (a // b) * y1\n \n    return gcd, x, y\n\ndef add_multi_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(2*n+2)\n    # Write your code here:\n    qc.compose(qft(n+1),qubits = list(range(n+1,2*n+2)), inplace=True)\n    for i in range(n):\n        qc.compose(add_mod(n,(a*2**i)%L,L),qubits = [0,i+1]+list(range(n+1,2*n+2)), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(n+1,2*n+2)), inplace=True)\n\n    return qc\n\ndef add_mod(n: int, a: int, L: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 3)\n    # Write your code here:\n    qc.compose(shift(n+1,2**n-L+a).control(2), inplace=True)\n    qc.compose(qft(n+1).inverse(),qubits = list(range(2,n+3)), inplace=True)\n    qc.compose(pack(n,2**n-L+a,2**n+a), inplace=True)\n    qc.compose(qft(n+1),qubits = list(range(2,n+3)), inplace=True)\n    qc.compose(shift(n+1,a).control(2), inplace=True)\n\n    return qc\n\ndef pack(n: int, s: int, t: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 3)\n    # Write your code here:\n    qc.compose(qft(n),qubits = list(range(2,n+2)), inplace=True)\n    qc.compose(shift(n,-t).control(3),qubits = [0,1,n+2]+list(range(2,n+2)), inplace=True)\n    qc.x(n+2)\n    qc.compose(shift(n,-s).control(3),qubits = [0,1,n+2]+list(range(2,n+2)), inplace=True)\n    qc.x(n+2)\n    qc.compose(qft(n).inverse(),qubits = list(range(2,n+2)), inplace=True)\n    return qc\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n    for i in range(n-1,-1,-1):\n        qc.h(i)\n        for j in range(i-1,-1,-1):\n            qc.cp(2*math.pi/2**(i-j+1),j,i)\n    for k in range(n//2):\n        qc.swap(k,n-1-k)\n    return qc\n\ndef shift(n,a):\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2*math.pi*a/2**(n-i),i)\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A44322E5E4FC3", "submission_order": 1, "result": "WA", "execution_time": "1719 ms", "memory": "166 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Create uniform superposition on input register\n    for i in range(n):\n        qc.h(x[i])\n    \n    # Step 2: For each basis state |k⟩, compute a^k mod L\n    for k in range(n):\n        # For each qubit in k's binary representation\n        power = 2**k\n        # If kth qubit is 1, multiply by a^(2^k) mod L\n        controlled_modmult(qc, x[k], y, a**power % L, L, m)\n    \n    return qc\n\ndef controlled_modmult(qc, control, target_reg, factor, modulus, m):\n    \"\"\"\n    Applies controlled modular multiplication:\n    If control=1: |y⟩ → |y * factor mod modulus⟩\n    \"\"\"\n    n_target = len(target_reg)\n    \n    # Convert factor to binary representation\n    bin_factor = format(factor % modulus, f'0{n_target}b')\n    \n    # Apply CNOT gates based on binary representation of factor\n    for i, bit in enumerate(reversed(bin_factor)):\n        if bit == '1':\n            qc.cx(control, target_reg[i])\n    \n    # Apply modular reduction\n    # This is a simplified version - in practice, you'd need\n    # a more sophisticated quantum modular arithmetic implementation\n    # that handles the modular reduction in a reversible way\n'''"}
{"problem": "QPC004_C5", "user": "A44322E5E4FC3", "submission_order": 2, "result": "WA", "execution_time": "1679 ms", "memory": "162 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    \n    # Step 1: Create uniform superposition on input register\n    for i in range(n):\n        qc.h(x[i])\n    \n    # Step 2: For each basis state |k⟩, compute a^k mod L\n    for k in range(n):\n        # For each qubit in k's binary representation\n        power = 2**k\n        # If kth qubit is 1, multiply by a^(2^k) mod L\n        controlled_modmult(qc, x[k], y, a**power % L, L, m)\n    \n    return qc\n\ndef controlled_modmult(qc, control, target_reg, factor, modulus, m):\n    \"\"\"\n    Applies controlled modular multiplication:\n    If control=1: |y⟩ → |y * factor mod modulus⟩\n    \"\"\"\n    n_target = len(target_reg)\n    \n    # Convert factor to binary representation\n    bin_factor = format(factor % modulus, f'0{n_target}b')\n    \n    # Apply CNOT gates based on binary representation of factor\n    for i, bit in enumerate(reversed(bin_factor)):\n        if bit == '1':\n            qc.cx(control, target_reg[i])\n    \n    # Apply modular reduction\n    # This is a simplified version - in practice, you'd need\n    # a more sophisticated quantum modular arithmetic implementation\n    # that handles the modular reduction in a reversible way\n'''"}
{"problem": "QPC004_C5", "user": "A5A72EC447696", "submission_order": 1, "result": "RE", "execution_time": "1530 ms", "memory": "157 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    def add_constant(qc, const, reg, controls):\n        if const == 0:\n            return\n        n_reg = len(reg)\n        for i in range(n_reg):\n            if (const & (1 << i)):\n                sub_reg = reg[i:]\n                ctrl_list = controls[:]\n                if len(ctrl_list) > 0:\n                    qc.mcx(ctrl_list, sub_reg[0])\n                else:\n                    qc.x(sub_reg[0])\n                for k in range(1, len(sub_reg)):\n                    ctrl_list = controls + sub_reg[0:k]\n                    qc.mcx(ctrl_list, sub_reg[k])\n\n    def modular_add_constant(qc, const, reg, L, controls):\n        if const == 0:\n            return\n        add_constant(qc, const, reg, controls)\n        temp = (1 << len(reg)) - L\n        add_constant(qc, temp, reg, controls)\n        add_constant(qc, L, reg, controls + [reg[-1]])\n\n    qc.h(x)\n    qc.x(y[0])\n    z_reg = y[0:m]\n    aux_reg = y[m:2*m+1]\n    for j in range(n):\n        c = pow(a, 1 << j, L)\n        if c == 0 or c == 1:\n            continue\n        inv = pow(c, -1, L)\n        neg_inv = L - inv\n        # CMULT c\n        for bit in range(m):\n            ctrl2 = z_reg[bit]\n            e = (c * (1 << bit)) % L\n            modular_add_constant(qc, e, aux_reg, L, [x[j], ctrl2])\n        # cswap\n        for bit in range(m):\n            qc.cswap(x[j], z_reg[bit], aux_reg[bit])\n        # CMULT neg_inv\n        for bit in range(m):\n            ctrl2 = z_reg[bit]\n            e = (neg_inv * (1 << bit)) % L\n            modular_add_constant(qc, e, aux_reg, L, [x[j], ctrl2])\n\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A5A72EC447696", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom __future__ import annotations\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import QFT         # ∣x⟩↦∣x̃⟩ helper\n# ------------------------------------------------------------------\n# elementary arithmetic gadgets\n# ------------------------------------------------------------------\ndef qft_add_const(qc: QuantumCircuit, q: list, c: int) -> None:\n    \"\"\" |x⟩  → |x+c mod 2^k⟩   (no ancilla, k = len(q))\n        little-endian QFT adder (Cuccaro, Draper 2000) \"\"\"\n    k = len(q)\n    qc.append(QFT(k, do_swaps=False).to_gate(label='QFT'), q)\n    for j in range(k):\n        angle = 2*pi*((c % (1<<k)) >> j) / (1 << (j+1))\n        if abs(angle) > 1e-12:\n            qc.p(angle, q[j])\n    qc.append(QFT(k, do_swaps=False).inverse().to_gate(label='QFT†'), q)\n\n\ndef add_const_mod(qc: QuantumCircuit,\n                  tgt: list,                       # k  value qubits  (little-endian)\n                  c: int,                          # classical const  (0 ≤ c < L)\n                  L: int,                          # modulus\n                  flag: int) -> None:              # *one* ancilla qubit inside tgt-register\n    \"\"\" |x⟩|0⟩  → |(x+c) mod L⟩|0⟩\n        *flag* is the MSB of *tgt*: we recycle it as the “overflow” bit.\n\n        Steps   (all reversible):\n        1.  x ← x+c                    (plain addition)\n        2.  x-L?  set flag if x ≥ L    (comparator)\n        3.  conditional −L             (controlled on flag)\n        4.  uncompute comparator       (flag back to |0⟩)\n    \"\"\"\n    k = len(tgt)-1                     # data bits 0…k-1, flag at k\n    data = tgt[:k]                     # shorthand\n    fbit = tgt[k]\n\n    # 1. add c\n    qft_add_const(qc, data, c)\n\n    # 2. compute “x ≥ L”  (compare to L-1 in two’s complement):\n    inv = ((1 << k) - L)               # actually add (2^k − L)\n    qft_add_const(qc, data, inv)       # x ← x + 2^k - L   (mod 2^k)\n    qc.x(data[-1])                     # MSB is 0  ↔  overflow  (‖ 2’s-complement sign)\n    qc.cx(data[-1], fbit)              # copy sign into flag\n    qc.x(data[-1])\n\n    # 3. if overflow, add L back\n    qft_add_const(qc, data, (L if c else 0))      # tidy up phase\n    qc.cx(fbit, data[-1])\n    qc.x(data[-1])\n    qc.cx(data[-1], fbit)\n    qft_add_const(qc, data, (1 << k) - L)         # undo comparator residue\n\n    # 4. uncompute flag\n    qft_add_const(qc, data, (1 << k) - c)         # restore original basis\n    qc.cx(data[-1], fbit)                         # flag back to |0〉\n    qft_add_const(qc, data, c)                    # data contains (x+c) mod L\n\n\ndef controlled_mul_const_mod(qc: QuantumCircuit,\n                             ctl, tgt: list, const: int, L: int) -> None:\n    \"\"\"If ctl==1 multiply |y⟩ by fixed *const* modulo L   (textbook “double-and-add”).\n\n       Uses the upper m ancilla qubits already available inside *tgt*.\n    \"\"\"\n    k = (len(tgt) - 1) // 2            # k = m\n    acc   = tgt[:k]                    # low  m  qubits – current value\n    work  = tgt[k:2*k]                 # upper m qubits – scratch (starts/ends |0⟩)\n    flag  = tgt[-1]                    # one shared ancilla\n\n    # copy acc into work so that we can accumulate there\n    for j in range(k):\n        qc.cx(acc[j], work[j])\n\n    for j in range(k):                 # multiply via “shift-add”\n        bit_const = (const >> j) & 1\n        if bit_const:\n            # add (2^j mod L) * y   controlled on ctl & acc[j]\n            cc = QuantumCircuit(1, name=f'×{const}·2^{j}')\n            add_const_mod(qc, work + [flag], (const << j) % L, L, flag)\n            for t in [*work, flag]:\n                qc.cx(ctl, t).c_if(acc[j], 1)     # dual control: ctl & acc[j]\n\n    # swap result into low register, clean ancilla\n    for j in range(k):\n        qc.cx(work[j], acc[j])\n        qc.cx(acc[j], work[j])\n        qc.cx(work[j], acc[j])\n\n# ------------------------------------------------------------------\n# complete solution\n# ------------------------------------------------------------------\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Prepares  (1/√2^n) Σ_k |k⟩ |a^k mod L⟩     with *real* modular arithmetic.\n    Register layout (little-endian):\n        x  : n          exponent qubits\n        y  : m          value   qubits         –  current number   (< L ≤ 2^m)\n             m          work    ancillae       –  scratch that returns to |0〉\n             1          overflow flag\n    \"\"\"\n    x = QuantumRegister(n,          'x')\n    y = QuantumRegister(2 * m + 1,  'y')\n    qc = QuantumCircuit(x, y)\n\n    # |k〉 superposition\n    qc.h(x)\n\n    # initialise y to 1 (multiplicative identity)\n    qc.x(y[0])\n\n    # repeated-squaring table  a^{2^i} (mod L)\n    powers = [pow(a, 1 << i, L) for i in range(n)]\n\n    # for each exponent bit apply controlled modular-multiplication\n    for i, const in enumerate(powers):\n        if const != 1:                          # skip no-op factors\n            controlled_mul_const_mod(qc, x[i], list(y), const, L)\n\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A5A72EC447696", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import QFT         # ∣x⟩↦∣x̃⟩ helper\n# ------------------------------------------------------------------\n# elementary arithmetic gadgets\n# ------------------------------------------------------------------\ndef qft_add_const(qc: QuantumCircuit, q: list, c: int) -> None:\n    \"\"\" |x⟩  → |x+c mod 2^k⟩   (no ancilla, k = len(q))\n        little-endian QFT adder (Cuccaro, Draper 2000) \"\"\"\n    k = len(q)\n    qc.append(QFT(k, do_swaps=False).to_gate(label='QFT'), q)\n    for j in range(k):\n        angle = 2*pi*((c % (1<<k)) >> j) / (1 << (j+1))\n        if abs(angle) > 1e-12:\n            qc.p(angle, q[j])\n    qc.append(QFT(k, do_swaps=False).inverse().to_gate(label='QFT†'), q)\n\n\ndef add_const_mod(qc: QuantumCircuit,\n                  tgt: list,                       # k  value qubits  (little-endian)\n                  c: int,                          # classical const  (0 ≤ c < L)\n                  L: int,                          # modulus\n                  flag: int) -> None:              # *one* ancilla qubit inside tgt-register\n    \"\"\" |x⟩|0⟩  → |(x+c) mod L⟩|0⟩\n        *flag* is the MSB of *tgt*: we recycle it as the “overflow” bit.\n\n        Steps   (all reversible):\n        1.  x ← x+c                    (plain addition)\n        2.  x-L?  set flag if x ≥ L    (comparator)\n        3.  conditional −L             (controlled on flag)\n        4.  uncompute comparator       (flag back to |0⟩)\n    \"\"\"\n    k = len(tgt)-1                     # data bits 0…k-1, flag at k\n    data = tgt[:k]                     # shorthand\n    fbit = tgt[k]\n\n    # 1. add c\n    qft_add_const(qc, data, c)\n\n    # 2. compute “x ≥ L”  (compare to L-1 in two’s complement):\n    inv = ((1 << k) - L)               # actually add (2^k − L)\n    qft_add_const(qc, data, inv)       # x ← x + 2^k - L   (mod 2^k)\n    qc.x(data[-1])                     # MSB is 0  ↔  overflow  (‖ 2’s-complement sign)\n    qc.cx(data[-1], fbit)              # copy sign into flag\n    qc.x(data[-1])\n\n    # 3. if overflow, add L back\n    qft_add_const(qc, data, (L if c else 0))      # tidy up phase\n    qc.cx(fbit, data[-1])\n    qc.x(data[-1])\n    qc.cx(data[-1], fbit)\n    qft_add_const(qc, data, (1 << k) - L)         # undo comparator residue\n\n    # 4. uncompute flag\n    qft_add_const(qc, data, (1 << k) - c)         # restore original basis\n    qc.cx(data[-1], fbit)                         # flag back to |0〉\n    qft_add_const(qc, data, c)                    # data contains (x+c) mod L\n\n\ndef controlled_mul_const_mod(qc: QuantumCircuit,\n                             ctl, tgt: list, const: int, L: int) -> None:\n    \"\"\"If ctl==1 multiply |y⟩ by fixed *const* modulo L   (textbook “double-and-add”).\n\n       Uses the upper m ancilla qubits already available inside *tgt*.\n    \"\"\"\n    k = (len(tgt) - 1) // 2            # k = m\n    acc   = tgt[:k]                    # low  m  qubits – current value\n    work  = tgt[k:2*k]                 # upper m qubits – scratch (starts/ends |0⟩)\n    flag  = tgt[-1]                    # one shared ancilla\n\n    # copy acc into work so that we can accumulate there\n    for j in range(k):\n        qc.cx(acc[j], work[j])\n\n    for j in range(k):                 # multiply via “shift-add”\n        bit_const = (const >> j) & 1\n        if bit_const:\n            # add (2^j mod L) * y   controlled on ctl & acc[j]\n            cc = QuantumCircuit(1, name=f'×{const}·2^{j}')\n            add_const_mod(qc, work + [flag], (const << j) % L, L, flag)\n            for t in [*work, flag]:\n                qc.cx(ctl, t).c_if(acc[j], 1)     # dual control: ctl & acc[j]\n\n    # swap result into low register, clean ancilla\n    for j in range(k):\n        qc.cx(work[j], acc[j])\n        qc.cx(acc[j], work[j])\n        qc.cx(work[j], acc[j])\n\n# ------------------------------------------------------------------\n# complete solution\n# ------------------------------------------------------------------\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Prepares  (1/√2^n) Σ_k |k⟩ |a^k mod L⟩     with *real* modular arithmetic.\n    Register layout (little-endian):\n        x  : n          exponent qubits\n        y  : m          value   qubits         –  current number   (< L ≤ 2^m)\n             m          work    ancillae       –  scratch that returns to |0〉\n             1          overflow flag\n    \"\"\"\n    x = QuantumRegister(n,          'x')\n    y = QuantumRegister(2 * m + 1,  'y')\n    qc = QuantumCircuit(x, y)\n\n    # |k〉 superposition\n    qc.h(x)\n\n    # initialise y to 1 (multiplicative identity)\n    qc.x(y[0])\n\n    # repeated-squaring table  a^{2^i} (mod L)\n    powers = [pow(a, 1 << i, L) for i in range(n)]\n\n    # for each exponent bit apply controlled modular-multiplication\n    for i, const in enumerate(powers):\n        if const != 1:                          # skip no-op factors\n            controlled_mul_const_mod(qc, x[i], list(y), const, L)\n\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A5A72EC447696", "submission_order": 4, "result": "RE", "execution_time": "1844 ms", "memory": "158 MiB", "code": "'''python\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n# ──────────────────────────────────────────────────────────────\n# 1.  In-place QFT / inverse QFT  (little-endian, no final swaps)\n# ──────────────────────────────────────────────────────────────\ndef qft(qc: QuantumCircuit, qubits) -> None:\n    \"\"\"Quantum Fourier Transform on *qubits* (little-endian, in-place).\"\"\"\n    n = len(qubits)\n    for j in range(n):\n        qc.h(qubits[j])\n        for k in range(j + 1, n):\n            qc.cp(pi / (1 << (k - j)), qubits[k], qubits[j])\n\n\ndef iqft(qc: QuantumCircuit, qubits) -> None:\n    \"\"\"Inverse QFT matching qft().\"\"\"\n    n = len(qubits)\n    for j in reversed(range(n)):\n        for k in reversed(range(j + 1, n)):\n            qc.cp(-pi / (1 << (k - j)), qubits[k], qubits[j])\n        qc.h(qubits[j])\n\n\n# ──────────────────────────────────────────────────────────────\n# 2.  QFT-based in-register constant adder  (little-endian)\n# ──────────────────────────────────────────────────────────────\ndef qft_add_const(qc: QuantumCircuit, q, c: int) -> None:\n    \"\"\"|x⟩ → |x+c mod 2^k⟩   on little-endian register *q* (k = len(q)).\"\"\"\n    k = len(q)\n    qft(qc, q)\n    for j in range(k):\n        angle = 2 * pi * ((c % (1 << k)) >> j) / (1 << (j + 1))\n        if abs(angle) > 1e-12:\n            qc.p(angle, q[j])\n    iqft(qc, q)\n\n\n# ──────────────────────────────────────────────────────────────\n# 3.  Add-constant-mod-L gadget   (Cuccaro comparator trick)\n# ──────────────────────────────────────────────────────────────\ndef add_const_mod(qc: QuantumCircuit, tgt: list, c: int, L: int, flag):\n    \"\"\"\n    Reversible: |x⟩|0⟩ ↦ |(x+c) mod L⟩|0⟩.\n    *tgt*  : k+1 qubits  (k data, 1 overflow flag  = tgt[-1] = *flag*)\n    *c*    : classical integer < L\n    *L*    : modulus (≤ 2^k)\n    \"\"\"\n    k = len(tgt) - 1\n    data = tgt[:k]\n\n    # 1. x ← x + c (mod 2^k)\n    qft_add_const(qc, data, c)\n\n    # 2. compute overflow : if x ≥ L copy sign bit into flag\n    qft_add_const(qc, data, (1 << k) - L)      # add 2^k − L\n    qc.x(data[-1])\n    qc.cx(data[-1], flag)\n    qc.x(data[-1])\n\n    # 3. conditional −L  (only if overflow flag = 1)\n    qc.ctrl(1)\n    qft_add_const(qc, data, L)                 # add L back  (controlled)\n    qc.ctrl(0)\n\n    # 4. uncompute comparator & restore basis\n    qft_add_const(qc, data, L - c)             # net effect: +(1<<k)−L−c\n    qc.cx(data[-1], flag)\n    qft_add_const(qc, data, c)                 # final value  (x+c) mod L\n\n\n# ──────────────────────────────────────────────────────────────\n# 4.  Controlled “× const  (mod L)” via double-and-add\n# ──────────────────────────────────────────────────────────────\ndef controlled_mul_const_mod(qc: QuantumCircuit, ctl, tgt: list,\n                             const: int, L: int) -> None:\n    \"\"\"If *ctl*==1 multiply |y⟩ by *const* modulo L in-place.\"\"\"\n    m = (len(tgt) - 1) // 2\n    acc  = tgt[:m]          # value register\n    work = tgt[m:2 * m]     # scratch (starts/ends |0⟩)\n    flag = tgt[-1]\n\n    # copy acc → work   (so we can accumulate result in *work*)\n    for j in range(m):\n        qc.cx(acc[j], work[j])\n\n    # “shift–add” multiply\n    for j in range(m):\n        if (const >> j) & 1:\n            # add (2^j · acc)  controlled on ctl & acc[j]\n            qc.ccx(ctl, acc[j], flag)          # create combined control in *flag*\n            add_const_mod(qc, work + [flag], (const << j) % L, L, flag)\n            qc.ccx(ctl, acc[j], flag)          # uncompute flag\n\n    # swap result into acc, clear work\n    for j in range(m):\n        qc.cx(work[j], acc[j])\n        qc.cx(acc[j], work[j])\n        qc.cx(work[j], acc[j])\n\n\n# ──────────────────────────────────────────────────────────────\n# 5.  Complete solver\n# ──────────────────────────────────────────────────────────────\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    \"\"\"\n    Prepare  |A⟩ = 2^{-n/2} Σ_k |k⟩ |a^k mod L⟩   with genuine modular arithmetic.\n    Layout (little-endian):\n        x : n               – exponent\n        y : m               – value\n            m               – work\n            1               – overflow flag\n    \"\"\"\n    x = QuantumRegister(n,          'x')\n    y = QuantumRegister(2 * m + 1,  'y')\n    qc = QuantumCircuit(x, y)\n\n    # uniform superposition over |k⟩\n    qc.h(x)\n\n    # initial value register ← 1\n    qc.x(y[0])\n\n    # repeated-squaring table  a^{2^i} (mod L)\n    powers = [pow(a, 1 << i, L) for i in range(n)]\n\n    # modular exponentiation by controlled multiplications\n    for i, const in enumerate(powers):\n        if const != 1:\n            controlled_mul_const_mod(qc, x[i], list(y), const, L)\n\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "A9FDBB0D03A25", "submission_order": 1, "result": "AC", "execution_time": "6922 ms", "memory": "192 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nimport math\n\n\ndef make_control(g, bit):\n    return g if bit == 0 else g.control(bit)\n\n\nclass QArith:\n    @staticmethod\n    def qft(n):\n        qc = QuantumCircuit(n)\n\n        thetas = []\n        for k in range(0, 1 + n):\n            thetas.append(2 * math.pi / (2**k))\n\n        for idx in range(0, n):\n            qc.h(n - 1 - idx)\n            for jdx in range(idx + 1, n):\n                thetaidx = jdx - idx + 1\n                qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n        for idx in range(0, n // 2):\n            qc.swap(idx, n - idx - 1)\n\n        return qc\n\n    @staticmethod\n    def add_const(n: int, add: int, control_bits: int = 0) -> QuantumCircuit:\n        from qiskit.circuit.library.standard_gates import PhaseGate\n\n        k, control = QuantumRegister(n), QuantumRegister(control_bits)\n        qc = QuantumCircuit(k, control)\n\n        q = QArith.qft(n)\n        qc.compose(q, inplace=True)\n\n        for idx in range(n):\n            theta = 2 * add * math.pi * (2**idx) / (2**n)\n            p = make_control(PhaseGate(theta), control_bits)\n            qc.append(p, [*control, k[idx]])\n\n        qc.compose(q.inverse(), inplace=True)\n\n        return qc\n\n    @staticmethod\n    def modadd_const(n: int, a: int, mod: int, control_bits: int = 0) -> QuantumCircuit:\n        regin, control = QuantumRegister(n + 1), QuantumRegister(control_bits)\n        qc = QuantumCircuit(regin, control)\n\n        def _separate_rot(n: int, s: int, t: int, control_bits: int = 0) -> QuantumCircuit:\n            from qiskit.circuit.library import XGate\n\n            regin, control = QuantumRegister(n + 1), QuantumRegister(control_bits)\n            qc = QuantumCircuit(regin, control)\n\n            mcx = make_control(XGate(), control_bits)\n\n            qc.append(mcx, [*control, regin[-1]])\n            qc.compose(QArith.add_const(n, -s, 1 + control_bits), inplace=True)\n            qc.append(mcx, [*control, regin[-1]])\n            qc.compose(\n                QArith.add_const(n, 2 ** (n + 1) - t, 1 + control_bits),\n                inplace=True,\n            )\n\n            return qc\n\n        qc.compose(\n            QArith.add_const(n + 1, 2**n - mod + a, control_bits),\n            inplace=True,\n        )\n        qc.compose(_separate_rot(n, 2**n - mod + a, 2**n + a, control_bits), inplace=True)\n        qc.compose(QArith.add_const(n + 1, a, control_bits), inplace=True)\n\n        return qc\n\n    @staticmethod\n    def modmult_const(n: int, a: int, mod: int, control_bits: int = 0) -> QuantumCircuit:\n        \"\"\"|x>|y> -> |x>|y+ax>\"\"\"\n        x, y, control = QuantumRegister(n), QuantumRegister(n + 1), QuantumRegister(control_bits)\n        qc = QuantumCircuit(x, y, control)\n\n        for idx in range(n):\n            add = a * (2**idx) % mod\n            qc.compose(QArith.modadd_const(n, add, mod, 1 + control_bits), [*y, *control, x[idx]], inplace=True)\n\n        return qc\n\n    @staticmethod\n    def modmult_const_inplace(n: int, a: int, mod: int, control_bits: int = 0) -> QuantumCircuit:\n        \"\"\"|x>|0> -> |ax>|0>\"\"\"\n        from qiskit.circuit.library import SwapGate\n\n        x, y, control = QuantumRegister(n), QuantumRegister(n + 1), QuantumRegister(control_bits)\n        qc = QuantumCircuit(x, y, control)\n\n        qc.compose(QArith.modmult_const(n, a, mod, control_bits), inplace=True)\n\n        cswap = make_control(SwapGate(), control_bits)\n        for idx in range(n):\n            qc.append(cswap, [*control, x[idx], y[idx]])\n\n        qc.compose(QArith.modmult_const(n, -pow(a, -1, mod), mod, control_bits), inplace=True)\n\n        return qc\n\n\ndef solve(n: int, m: int, a: int, mod: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n\n    qc.h(x)\n    qc.x(y[0])\n    for idx in range(n):\n        multpow = QArith.modmult_const_inplace(m, pow(a, 2**idx, mod), mod, 1)\n        qc.compose(multpow, [*y, x[idx]], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC004_C5", "user": "AE61DC7EA731D", "submission_order": 1, "result": "RE", "execution_time": "2268 ms", "memory": "158 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int, m: int, a: int, L: int) -> QuantumCircuit:\n    x, y = QuantumRegister(n), QuantumRegister(2 * m + 1)\n    qc = QuantumCircuit(x, y)\n    # Write your code here:\n    for i in range(n):\n        qc.h(x[i])\n        qc.x(y[0])\n        d=2**(2*m+1)\n    def U(r):\n        M=np.zeros((d,d),dtype=complex)\n        for i in range(d):\n            j=(i*r)%L if i<L else i\n            M[j,i]=1\n        return M\n    for j in range(n):\n        r=pow(a,2**j,L)\n        gate=UnitaryGate(U(r),label=\"U\"+str(r))\n        cgate=gate.control(1)\n        qc.append(cgate,[x[j]]+list(y))\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A05D5FC6BBAE2", "submission_order": 1, "result": "AC", "execution_time": "1548 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A06E382F5D541", "submission_order": 1, "result": "AC", "execution_time": "1505 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A0BE9E26E580F", "submission_order": 1, "result": "AC", "execution_time": "1694 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A0BEEF60F4768", "submission_order": 1, "result": "AC", "execution_time": "1780 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A0F0BFC24656B", "submission_order": 1, "result": "AC", "execution_time": "1476 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A1582663DF007", "submission_order": 1, "result": "WA", "execution_time": "1576 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A1582663DF007", "submission_order": 2, "result": "WA", "execution_time": "1599 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A1582663DF007", "submission_order": 3, "result": "AC", "execution_time": "1431 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A1F54CA412CF2", "submission_order": 1, "result": "AC", "execution_time": "1619 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A2BA1C068EDF5", "submission_order": 1, "result": "AC", "execution_time": "1648 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A2D03F3B4C72E", "submission_order": 1, "result": "RE", "execution_time": "1525 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x()\n    qc.h()\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A2D03F3B4C72E", "submission_order": 2, "result": "WA", "execution_time": "1577 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A2D03F3B4C72E", "submission_order": 3, "result": "AC", "execution_time": "1761 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    \n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A2EDD68B9135A", "submission_order": 1, "result": "AC", "execution_time": "1726 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve():\n    qc = QuantumCircuit(1)\n    qc.x(range(1))\n    qc.h(range(1))\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A32705E0407B6", "submission_order": 1, "result": "AC", "execution_time": "1635 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A35DF60212067", "submission_order": 1, "result": "AC", "execution_time": "1614 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A3AE260FA7444", "submission_order": 1, "result": "WA", "execution_time": "1599 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A3AE260FA7444", "submission_order": 2, "result": "AC", "execution_time": "1598 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A3CD30B16E678", "submission_order": 1, "result": "AC", "execution_time": "1650 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A4331BE1D88F8", "submission_order": 1, "result": "AC", "execution_time": "1660 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A487BE2155FD7", "submission_order": 1, "result": "AC", "execution_time": "1533 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A49922F869F23", "submission_order": 1, "result": "AC", "execution_time": "1776 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A51C3E261CD21", "submission_order": 1, "result": "AC", "execution_time": "1661 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A5274E872E9EA", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = qc.0\n    qc = qc.minus\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A5274E872E9EA", "submission_order": 2, "result": "RE", "execution_time": "1590 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc=qc.x(0)\n    qc=qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A5274E872E9EA", "submission_order": 3, "result": "AC", "execution_time": "1700 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A5B31B5EB6667", "submission_order": 1, "result": "AC", "execution_time": "1699 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A5E4EA4DA33F5", "submission_order": 1, "result": "AC", "execution_time": "1543 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A5FAB0EA612F5", "submission_order": 1, "result": "AC", "execution_time": "1604 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A6A59B946F777", "submission_order": 1, "result": "AC", "execution_time": "1673 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, PhaseGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A6C87E094CE61", "submission_order": 1, "result": "AC", "execution_time": "1659 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A6F65BB19E586", "submission_order": 1, "result": "RE", "execution_time": "1658 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0) \n    qc.cx(0, 1)\n    qc.h(0)\n    qc.cx(0, 1)\n    \n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A6F65BB19E586", "submission_order": 2, "result": "AC", "execution_time": "1506 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0) \n    qc.h(0)\n    \n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A72EFDE62ABFF", "submission_order": 1, "result": "AC", "execution_time": "1617 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A791BAB14EE0A", "submission_order": 1, "result": "WA", "execution_time": "1625 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)  # Xゲート\n    qc.z(0)  # Zゲート  \n    qc.x(0)  # Xゲート\n    return qc\n\nprint(solve().draw())\n'''"}
{"problem": "QPC005_A1", "user": "A791BAB14EE0A", "submission_order": 2, "result": "RE", "execution_time": "1367 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.initialize(initial_state, 0)\n    qc.x(0)  # Xゲート\n    qc.z(0)  # Zゲート  \n    qc.x(0)  # Xゲート\n    return qc\n\nprint(solve().draw())\n'''"}
{"problem": "QPC005_A1", "user": "A791BAB14EE0A", "submission_order": 3, "result": "AC", "execution_time": "1547 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    return qc\n\nprint(solve().draw())\n'''"}
{"problem": "QPC005_A1", "user": "A83DAC814D178", "submission_order": 1, "result": "AC", "execution_time": "1701 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A8DA370228755", "submission_order": 1, "result": "AC", "execution_time": "1652 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A8FF3D621FF36", "submission_order": 1, "result": "AC", "execution_time": "1531 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A917F53FD43EC", "submission_order": 1, "result": "AC", "execution_time": "1672 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A9B3BB9338454", "submission_order": 1, "result": "AC", "execution_time": "1531 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "A9F155ED37DD1", "submission_order": 1, "result": "AC", "execution_time": "1602 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    \n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AA1062C37AFBE", "submission_order": 1, "result": "WA", "execution_time": "1653 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AA1062C37AFBE", "submission_order": 2, "result": "AC", "execution_time": "1530 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AA5A02268FB76", "submission_order": 1, "result": "WA", "execution_time": "1631 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AA5A02268FB76", "submission_order": 2, "result": "WA", "execution_time": "1648 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AA5A02268FB76", "submission_order": 3, "result": "AC", "execution_time": "1781 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AAC007E1F4D88", "submission_order": 1, "result": "AC", "execution_time": "1587 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AACFD70277773", "submission_order": 1, "result": "RE", "execution_time": "1564 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.H(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AACFD70277773", "submission_order": 2, "result": "WA", "execution_time": "1650 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AACFD70277773", "submission_order": 3, "result": "AC", "execution_time": "1616 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AB2CD68D466FF", "submission_order": 1, "result": "AC", "execution_time": "1825 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)   # Apply Hadamard to qubit 0\n    qc.z(0)   # Apply Z gate to qubit 0\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AB5C2E8C64018", "submission_order": 1, "result": "RE", "execution_time": "1545 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(1)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AB5C2E8C64018", "submission_order": 2, "result": "AC", "execution_time": "1448 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AB91A197AA331", "submission_order": 1, "result": "AC", "execution_time": "1611 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AC02EA26B1905", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nimport numpy as np\nimport scipy\nimport math\nfrom qiskit import QuantumCircuit\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library.standard_gates import *\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n\n    return qc\n\n\ndef main():\n    print(solve())\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A1", "user": "AC02EA26B1905", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import *\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n\n\ndef main():\n    print(solve())\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A1", "user": "AC02EA26B1905", "submission_order": 3, "result": "AC", "execution_time": "1675 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n\n\ndef main():\n    print(solve())\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A1", "user": "AC6BB99D06033", "submission_order": 1, "result": "AC", "execution_time": "1647 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AD0E1F9745D95", "submission_order": 1, "result": "RE", "execution_time": "1675 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.g(0)\n \n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AD0E1F9745D95", "submission_order": 2, "result": "WA", "execution_time": "1561 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.append(\n        RYGate(180),\n        [0],\n    )\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AD0E1F9745D95", "submission_order": 3, "result": "WA", "execution_time": "1402 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import RYGate\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.append(\n        RYGate(pi/2),\n        [0],\n    )\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AD0E1F9745D95", "submission_order": 4, "result": "AC", "execution_time": "1639 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.h(0)\n    qc.z(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AD21C42B7E5DE", "submission_order": 1, "result": "AC", "execution_time": "1932 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AD77DCB8F69E7", "submission_order": 1, "result": "RE", "execution_time": "1473 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x()\n    qc.h()\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AD77DCB8F69E7", "submission_order": 2, "result": "AC", "execution_time": "1735 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AD7BE18759B39", "submission_order": 1, "result": "AC", "execution_time": "1608 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "ADA2E89F897B4", "submission_order": 1, "result": "AC", "execution_time": "1611 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n\n    # Write your code here:\n    qc.h(0)\n    qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "ADA51738F21C3", "submission_order": 1, "result": "AC", "execution_time": "1433 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "ADBBD33667B4F", "submission_order": 1, "result": "AC", "execution_time": "1938 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AED15AA3A0086", "submission_order": 1, "result": "AC", "execution_time": "1615 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n\n    qc.x(0)\n    qc.h(0)\n \n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AF20F9DEB8FCD", "submission_order": 1, "result": "AC", "execution_time": "1626 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    \n    qc.h(0)\n    qc.z(0)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve()\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A1", "user": "AF62C655EB19D", "submission_order": 1, "result": "AC", "execution_time": "1499 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AFD2A99225539", "submission_order": 1, "result": "WA", "execution_time": "1629 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.z(0);\n    qc.h(0);\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AFD2A99225539", "submission_order": 2, "result": "AC", "execution_time": "1692 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0);\n    qc.h(0);\n    return qc\n'''"}
{"problem": "QPC005_A1", "user": "AFD2C30460D96", "submission_order": 1, "result": "AC", "execution_time": "1722 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve() -> QuantumCircuit:\n    qc = QuantumCircuit(1)\n    # Write your code here:\n    qc.x(0)\n    qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A0C33BF3B43DD", "submission_order": 1, "result": "AC", "execution_time": "2120 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i+1)\n\n    mc_h = HGate().control(n)\n    qc.append(mc_h, range(n, -1, -1))\n    for i in range(n):\n        qc.x(i+1)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A106443E27667", "submission_order": 1, "result": "AC", "execution_time": "1946 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k)\n    ch_gate = HGate().control(n)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.x(k)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A110497E0BD3E", "submission_order": 1, "result": "RE", "execution_time": "1410 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), [*k, m])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A110497E0BD3E", "submission_order": 2, "result": "AC", "execution_time": "2050 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), [*k, m])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A125BADCDB32E", "submission_order": 1, "result": "WA", "execution_time": "1662 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    mch_gate = HGate().control(n)\n    qc.append(mch_gate, range(n, -1, -1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A125BADCDB32E", "submission_order": 2, "result": "AC", "execution_time": "2314 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(k)\n\n    mch_gate = HGate().control(n)\n    qc.append(mch_gate, range(n, -1, -1))\n\n    qc.x(k)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A14D5D0942D6C", "submission_order": 1, "result": "RE", "execution_time": "1531 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), k, m)\n    qc.x(k)\n    qc.z(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A14D5D0942D6C", "submission_order": 2, "result": "RE", "execution_time": "1678 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), [k, m])\n    qc.x(k)\n    qc.z(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A14D5D0942D6C", "submission_order": 3, "result": "WA", "execution_time": "1765 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), list(range(1,n+1))+[0])\n    qc.x(k)\n    qc.z(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A14D5D0942D6C", "submission_order": 4, "result": "RE", "execution_time": "1421 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), [k,m])\n    qc.x(k)\n    qc.z(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A14D5D0942D6C", "submission_order": 5, "result": "WA", "execution_time": "1761 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n    qc.x(k)\n    qc.append(HGate().control(n), list(range(1,n+1))+[0])\n    qc.x(k)\n    qc.z(m)\n    qc.x(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A14D5D0942D6C", "submission_order": 6, "result": "WA", "execution_time": "1671 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), range(n+1))#list(range(1,n+1))+[0])\n    qc.x(k)\n    qc.z(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A14D5D0942D6C", "submission_order": 7, "result": "AC", "execution_time": "2009 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), list(range(1,n+1))+[0])\n    qc.x(k)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 1, "result": "WA", "execution_time": "1655 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    if m == 0:\n        qc.h(0)\n        qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 2, "result": "WA", "execution_time": "1680 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    if k == 0:\n        qc.h(0)\n        qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 3, "result": "WA", "execution_time": "1677 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(1, n+1):\n        qc.x(i)\n\n    qc.h(0)\n    qc.cz(range(1, n+1), 0)\n  \n    for i in range(1, n+1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 4, "result": "WA", "execution_time": "1672 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(1, n+1):\n        qc.x(i)\n\n    qc.h(0)\n    qc.cz(range(1, n+1), 0)\n    qc.h(0)\n  \n    for i in range(1, n+1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 5, "result": "RE", "execution_time": "1558 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(1, n+1):\n        qc.x(i)\n\n    qc.h(0)\n    qc.append(ZGate().control(n), list(range(1, n+1)))\n    qc.h(0)\n  \n    for i in range(1, n+1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 6, "result": "RE", "execution_time": "1449 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(1, n+1):\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcz(list(range(1, n+1)) + [0])\n    qc.h(0)\n  \n    for i in range(1, n+1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 7, "result": "RE", "execution_time": "1419 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(1, n+1):\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcz(list(range(1, n+1)) + [0])\n    qc.h(0)\n  \n    for i in range(1, n+1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 8, "result": "RE", "execution_time": "1462 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(1, n+1):\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcz(list(range(1, n+1)), 0)\n    qc.h(0)\n  \n    for i in range(1, n+1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 9, "result": "RE", "execution_time": "1526 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(1, n+1):\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcz(range(1, n+1), 0)\n    qc.h(0)\n  \n    for i in range(1, n+1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 10, "result": "RE", "execution_time": "1480 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(n):\n        qc.x(k[i])\n\n    qc.h(m[0])\n    qc.mcz(k, m[0])\n    qc.h(m[0])\n  \n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 11, "result": "RE", "execution_time": "1581 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # Write your code here:\n    # k = 0 の場合を全て 1 が立つようにする\n    for i in range(1, n+1):\n        qc.x(i)\n\n    qc.h(0)\n    qc.mcz(range(1, n+1), 0)\n  \n    for i in range(1, n+1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 12, "result": "WA", "execution_time": "1657 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1, 'm'), QuantumRegister(n, 'k')\n    qc = QuantumCircuit(m, k)\n\n    for i in range(n):\n        qc.x(k[i])\n\n    qc.h(m[0])\n    if n == 1:\n        qc.cz(k[0], m[0])\n    else:\n        qc.mcx(list(k), m[0])\n    qc.h(m[0])\n\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 13, "result": "WA", "execution_time": "1697 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1, 'm'), QuantumRegister(n, 'k')\n    qc = QuantumCircuit(m, k)\n\n    for i in range(n):\n        qc.x(k[i])\n\n    qc.h(m[0])\n    if n == 1:\n        qc.cz(k[0], m[0])\n    else:\n        qc.mcx(list(k), m[0])\n\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 14, "result": "WA", "execution_time": "1494 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    for i in range(n):\n        qc.x(k[i])\n\n    qc.h(m[0])\n    if n == 1:\n        qc.cz(k[0], m[0])\n    else:\n        qc.mcx(list(k), m[0])\n\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 15, "result": "RE", "execution_time": "1469 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import MCXGate\n\ndef oracle_qc(n: int):\n    qc = QuantumCircuit(n + 2)  # m(1) + k(n) + ancilla(1)\n    m_idx = 0\n    k_idxs = list(range(1, n+1))\n    anc_idx = n + 1\n\n    # Step 1: ancillaをセット（k=0を検出）\n    for i in k_idxs:\n        qc.x(i)  # k_i=0 なら1になるよう反転\n    qc.mcx(k_idxs, anc_idx)  # 全ビットが0のとき ancilla = 1\n    for i in k_idxs:\n        qc.x(i)  # 元に戻す\n\n    # Step 2: ancillaが1ならmに対して変換を行う\n    qc.h(m_idx)\n    qc.cz(anc_idx, m_idx)\n    qc.h(m_idx)\n\n    # Step 3: ancillaをuncompute\n    for i in k_idxs:\n        qc.x(i)\n    qc.mcx(k_idxs, anc_idx)\n    for i in k_idxs:\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A197CCCE029AD", "submission_order": 16, "result": "AC", "execution_time": "1802 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n \n    qc.x(k)\n \n    qc.compose(HGate().control(len(k)), [*k, m[0]], inplace=True)\n \n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A22808B550521", "submission_order": 1, "result": "WA", "execution_time": "1768 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(k)\n    qc.append(HGate().control(n), reversed(range(0, n + 1)))\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A22808B550521", "submission_order": 2, "result": "WA", "execution_time": "2016 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(n), reversed(range(0, n + 1)))\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A22808B550521", "submission_order": 3, "result": "AC", "execution_time": "1928 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(k)\n    qc.append(HGate().control(n), reversed(range(0, n + 1)))\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A23514158FCF5", "submission_order": 1, "result": "RE", "execution_time": "1617 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(i for i in k)\n    qc.append(qc.h().control(m[0]), k)\n    qc.x(i for i in k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A23514158FCF5", "submission_order": 2, "result": "RE", "execution_time": "1733 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(i for i in k)\n    qc.qppend(HGate().control(0), range(n+1))\n    qc.x(i for i in k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A23514158FCF5", "submission_order": 3, "result": "AC", "execution_time": "1847 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(i for i in k)\n    qc.append(HGate().control(n), list(k) + [m[0]])\n    qc.x(i for i in k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A31D4ADCFC3F4", "submission_order": 1, "result": "WA", "execution_time": "1756 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.cx(k[n-1], m[0])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A325E6312DA26", "submission_order": 1, "result": "RE", "execution_time": "1474 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n\n\n\n    qc.append(HGate().control(n - 1), range(n))\n    qc.append(ZGate().control(0), [m[0]])\n\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A325E6312DA26", "submission_order": 2, "result": "RE", "execution_time": "1375 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n\n\n\n    qc.append(HGate().control(n), list(k) + [m])\n    qc.append(ZGate().control(n), list(k) + [m])\n\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A325E6312DA26", "submission_order": 3, "result": "RE", "execution_time": "1532 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n\n    qc.append(HGate().control(n), list(k) + [m])\n    qc.append(ZGate().control(n), list(k) + [m])\n\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A325E6312DA26", "submission_order": 4, "result": "WA", "execution_time": "1671 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n\n    qc.append(HGate().control(n), list(k) + [m])\n    qc.append(ZGate().control(n), list(k) + [m])\n\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A325E6312DA26", "submission_order": 5, "result": "RE", "execution_time": "1528 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n\n\n\n    qc.append(HGate().control(n - 1), range(n))\n    qc.append(ZGate().control(0), [m[0]])\n\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A3F863925BCE0", "submission_order": 1, "result": "AC", "execution_time": "1942 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.append(HGate().control(n, ctrl_state='0'*n), k[:] + [m[0]])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 1, "result": "RE", "execution_time": "1406 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.append(HGate().control(1), range(n+1))\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n# import math\n# from qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.append(HGate().control(1), range(n+1))\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 3, "result": "RE", "execution_time": "1593 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n# import math\n# from qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.append(HGate().control(1), range(n+1))\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 4, "result": "RE", "execution_time": "1441 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n# import math\n# from qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.append(HGate().control(1), range(n+1))\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 5, "result": "WA", "execution_time": "1558 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.append(HGate().control(n), range(n+1))\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 6, "result": "RE", "execution_time": "1418 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.append(HGate().control(n), [range(n+1), 0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 7, "result": "RE", "execution_time": "1395 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.append(HGate().control(n), [k, m])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 8, "result": "RE", "execution_time": "1548 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.append(HGate().control(n), [1, 0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 9, "result": "WA", "execution_time": "1881 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 10, "result": "WA", "execution_time": "1540 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    qc.x(m)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n    qc.x(m)\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 11, "result": "WA", "execution_time": "1671 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate, XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(XGate().control(n), [*control, 0])\n    qc.append(HGate().control(n), [*control, 0])\n    qc.append(XGate().control(n), [*control, 0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 12, "result": "WA", "execution_time": "1677 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 13, "result": "WA", "execution_time": "1745 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n    qc.x(k)\n    qc.h(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 14, "result": "WA", "execution_time": "1756 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 15, "result": "WA", "execution_time": "1599 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 16, "result": "RE", "execution_time": "1618 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(m)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [k, m])\n    qc.x(m)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 17, "result": "RE", "execution_time": "1412 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(m)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), k, m)\n    qc.x(m)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 18, "result": "RE", "execution_time": "1461 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(k)\n    qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [k, m])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 19, "result": "RE", "execution_time": "1469 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(m)\n    qc.h(k)\n    qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [k, m])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 20, "result": "RE", "execution_time": "1374 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(m)\n    qc.h(k)\n\n    qc.x(k)\n    qc.append(HGate().control(n), [m, k])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 21, "result": "RE", "execution_time": "1712 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(m)\n    qc.h(k)\n\n    qc.x(k)\n    qc.append(HGate().control(n), [1, 0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 22, "result": "WA", "execution_time": "2034 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(m)\n    qc.h(k)\n\n    qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 23, "result": "WA", "execution_time": "1712 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(m)\n    qc.h(k)\n\n    #qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n    #qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A449050A2EF73", "submission_order": 24, "result": "AC", "execution_time": "1784 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n# from qiskit.quantum_info import Statevector\nfrom qiskit import QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # qc.h(m)\n    # qc.h(k)\n\n    qc.x(k)\n    control = [i+1 for i in range(n)]\n    qc.append(HGate().control(n), [*control, 0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A52D13E7A88FF", "submission_order": 1, "result": "WA", "execution_time": "1792 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.h(m)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A52D13E7A88FF", "submission_order": 2, "result": "WA", "execution_time": "1565 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k)\n    qc.ch(k, m)\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A52D13E7A88FF", "submission_order": 3, "result": "AC", "execution_time": "2110 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k)\n    qc.append(HGate().control(n), [*k, *m])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A575097D03964", "submission_order": 1, "result": "RE", "execution_time": "1367 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + [m[0]])\n    qc.append(ZGate().control(n + 1), k[:] + [m[0]])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A575097D03964", "submission_order": 2, "result": "WA", "execution_time": "1566 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + [m[0]])\n    qc.append(ZGate().control(n), k[:] + [m[0]])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A575097D03964", "submission_order": 3, "result": "AC", "execution_time": "2041 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + [m[0]])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A5AC687BA3E09", "submission_order": 1, "result": "WA", "execution_time": "1762 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k==0:\n      qc.x(k)\n      qc.h(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A5AC687BA3E09", "submission_order": 2, "result": "WA", "execution_time": "1723 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k==0:\n      qc.x(m)\n      qc.h(m)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A5AC687BA3E09", "submission_order": 3, "result": "WA", "execution_time": "1630 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k==0:\n      qc.h(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A5AC687BA3E09", "submission_order": 4, "result": "WA", "execution_time": "1757 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k==0:\n      qc.h(k)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A5AC687BA3E09", "submission_order": 5, "result": "WA", "execution_time": "1651 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k==0:\n      qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A5AC687BA3E09", "submission_order": 6, "result": "WA", "execution_time": "1677 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k==0:\n      qc.h(m)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A5AC687BA3E09", "submission_order": 7, "result": "WA", "execution_time": "1613 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k==0:\n      qc.h(m[0])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 1, "result": "RE", "execution_time": "1587 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(x.control(n-1), range(n))\n    qc.append(h.control(n-1), range(n))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 2, "result": "RE", "execution_time": "1614 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(x.control(n), range(n+1))\n    qc.append(h.control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(x.control(n), range(n+1))\n    qc.append(h.control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import X, H\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(X.control(n), range(n+1))\n    qc.append(H.control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 5, "result": "RE", "execution_time": "1702 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(x(0).control(n), range(n+1))\n    qc.append(h(0).control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 6, "result": "RE", "execution_time": "1703 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), range(n+1))\n    qc.append(HGate().control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 7, "result": "RE", "execution_time": "1856 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), range(n+1))\n    qc.append(HGat().control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 8, "result": "RE", "execution_time": "1977 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), range(n+1))\n    qc.append(HGat().control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 9, "result": "WA", "execution_time": "2302 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), range(n+1))\n    qc.append(HGate().control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 10, "result": "RE", "execution_time": "1955 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(0), range(n+1))\n    qc.append(HGate().control(0), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 11, "result": "RE", "execution_time": "1673 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(0), list(k) + [m[0]])\n    qc.append(HGate().control(0), list(k) + [m[0]])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 12, "result": "WA", "execution_time": "1947 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), list(k) + [m[0]])\n    qc.append(HGate().control(n), list(k) + [m[0]])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A65636DFBE64B", "submission_order": 13, "result": "AC", "execution_time": "2087 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), list(k) + [m[0]])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A6EE6AC0152A6", "submission_order": 1, "result": "WA", "execution_time": "1759 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    aux = QuantumRegister(1, 'aux')\n    qc.add_register(aux)\n    \n    qc.x(aux[0])\n    \n    for i in range(n):\n        qc.cx(k[i], aux[0])\n    \n    qc.ch(aux[0], m[0])\n    \n    for i in range(n):\n        qc.cx(k[i], aux[0])\n    qc.x(aux[0])\n    \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A6EE6AC0152A6", "submission_order": 2, "result": "WA", "execution_time": "1558 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    controlled_h = HGate().control(n, ctrl_state='0' * n)\n    qc.append(controlled_h, k[:] + [m[0]])\n    \n    controlled_z = ZGate().control(n, ctrl_state='0' * n)\n    qc.append(controlled_z, k[:] + [m[0]])\n    \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A6EE6AC0152A6", "submission_order": 3, "result": "AC", "execution_time": "2110 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    controlled_h = HGate().control(n, ctrl_state='0' * n)\n    qc.append(controlled_h, k[:] + [m[0]])\n    \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A7B1AE9BD3F88", "submission_order": 1, "result": "AC", "execution_time": "2120 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    c0h = HGate().control(n, ctrl_state=0)\n    qc.append(c0h, list(range(1, n + 1)) + [0])\n\n    return qc\n\n\ndef main():\n    print(solve(1))\n    print(solve(2))\n    print(solve(3))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A2", "user": "A831609A06DB3", "submission_order": 1, "result": "WA", "execution_time": "1734 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.ch(k, m)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A831609A06DB3", "submission_order": 2, "result": "WA", "execution_time": "1673 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.ch(k, m)\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A831609A06DB3", "submission_order": 3, "result": "RE", "execution_time": "1405 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(len(k)), range(len(k),-1,-1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A831609A06DB3", "submission_order": 4, "result": "RE", "execution_time": "2049 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(len(k)), range(len(k),-1,-1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A831609A06DB3", "submission_order": 5, "result": "RE", "execution_time": "2135 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.compose(HGate().control(len(k)), [*k, m[0]], inplace=True)\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A831609A06DB3", "submission_order": 6, "result": "AC", "execution_time": "2304 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(len(k)), range(len(k),-1,-1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A84FBE06EF9E5", "submission_order": 1, "result": "AC", "execution_time": "2167 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), list(range(1, n+1))+[0])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 1, "result": "RE", "execution_time": "1440 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # Flip k so that controls are on '0'\n    for i in range(n):\n        qc.x(k[i])\n\n    # Multi-controlled Hadamard is hard; instead, we:\n    # Put state |m> through H, and then Z conditioned on m and all k==0\n    qc.h(m[0])\n    if n == 0:\n        # No controls, always act\n        qc.z(m[0])\n    else:\n        qc.mcz([m[0]] + [k[i] for i in range(n)], m[0])\n    # But Qiskit mcz does not allow target as part of controls!\n    # Instead, do controlled-Z on m[0], controlled by all k==0\n\n    if n > 0:\n        qc.mcz([k[i] for i in range(n)], m[0])\n\n    # Unflip k\n    for i in range(n):\n        qc.x(k[i])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 2, "result": "RE", "execution_time": "1368 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    # Invert all k qubits (check if they're in |0⟩)\n    for i in range(n):\n        qc.x(k[i])\n\n    # Apply multi-controlled Toffoli to m (using no ancilla)\n    if n == 1:\n        qc.cx(k[0], m[0])\n    elif n == 2:\n        qc.ccx(k[0], k[1], m[0])\n    else:\n        qc.mct(k[:], m[0], mode='noancilla')  # n ≥ 3\n\n    # Apply Z then H to m[0]\n    qc.z(m[0])\n    qc.h(m[0])\n\n    # Undo the Toffoli\n    if n == 1:\n        qc.cx(k[0], m[0])\n    elif n == 2:\n        qc.ccx(k[0], k[1], m[0])\n    else:\n        qc.mct(k[:], m[0], mode='noancilla')  # n ≥ 3\n\n    # Undo the X gates\n    for i in range(n):\n        qc.x(k[i])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 3, "result": "WA", "execution_time": "1990 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # Apply X gates to flip m if needed (controlled by k=0 condition)\n    # Use multi-controlled X gate to check if k == 0\n    qc.x(k)  # Flip all k qubits to test the inverse\n    qc.mcx(k, m)  # Multi-controlled X gate with k controlling m\n    qc.x(k)  # Flip back k qubits\n    # Apply Hadamard to m to get the superposition\n    qc.h(m)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 4, "result": "WA", "execution_time": "2356 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # Use an ancillary qubit approach to detect k = 0 and apply phase\n    qc.h(m)  # Start with Hadamard to get superposition\n    # Apply multi-controlled Z gate to introduce phase when k != 0\n    qc.mcx(k, m)  # Control on k qubits, target m (flips when k != 0)\n    qc.x(m)  # Correct the phase by flipping m\n    qc.h(m)  # Reapply Hadamard to adjust superposition\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 5, "result": "WA", "execution_time": "1542 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n# Apply transformation only when k = 0\n    qc.x(k)  # Flip k qubits to test k = 0 (all 1s means original k = 0)\n    qc.mcx(k, m)  # Multi-controlled X when k = 0\n    qc.h(m)  # Apply Hadamard to get superposition\n    qc.x(k)  # Restore k qubits\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 6, "result": "WA", "execution_time": "2094 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # Add an ancillary qubit to handle the control\n    anc = QuantumRegister(1, 'anc')\n    qc.add_register(anc)\n    # Initialize anc to |0>\n    qc.x(anc)  # anc = |1> for control inversion\n    # Check if k = 0 using multi-controlled X\n    qc.mcx(k, anc)  # anc flips to |0> only if k = 0\n    # Apply controlled Hadamard with phase\n    qc.ch(m, anc)  # Controlled Hadamard when anc = |1> (k != 0 does nothing)\n    qc.cz(m, anc)  # Apply phase based on m when anc = |1>\n    qc.x(anc)  # Reset anc\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 7, "result": "RE", "execution_time": "1407 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # Apply X gates to invert k for k = 0 condition\n    qc.x(k)  # Flip all k qubits (k = 0 becomes all |1>)\n    # Use multi-controlled Hadamard with phase\n    qc.mch(k, m)  # Multi-controlled Hadamard (approximates superposition)\n    qc.mcx(k, m)  # Apply controlled X to adjust phase\n    qc.x(k)  # Restore k qubits\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 8, "result": "WA", "execution_time": "2283 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n# Apply transformation only when k = 0\n    # Invert k to check k = 0 (all |1> means original k = 0)\n    for i in range(n):\n        qc.x(k[i])  # Flip each k qubit\n    # Apply controlled operation\n    qc.h(m)  # Start with Hadamard\n    for i in range(n):\n        qc.cx(k[i], m)  # Use CNOT to build control (approximates multi-control)\n    qc.h(m)  # Refine superposition\n    for i in range(n):\n        qc.x(k[i])  # Restore k qubits\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 9, "result": "RE", "execution_time": "2108 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n# Apply transformation only when k = 0\n    qc.x(k)  # Invert k (k = 0 becomes all |1>)\n    qc.mct(k, m)  # Multi-controlled Toffoli when k = 0\n    qc.h(m)  # Apply Hadamard to get superposition\n    qc.mct(k, m)  # Undo the control to adjust phase\n    qc.x(k)  # Restore k\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 10, "result": "WA", "execution_time": "1738 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n# Conditionally apply transformation when k = 0\n    for i in range(n):\n        qc.x(k[i])  # Invert k (k = 0 becomes all |1>)\n    # Use controlled operations to apply transformation\n    qc.h(m)  # Apply Hadamard\n    for i in range(n-1, -1, -1):  # Iterate backwards for control\n        qc.cx(k[i], m)  # Control on each k[i]\n    qc.h(m)  # Refine superposition\n    for i in range(n):\n        qc.x(k[i])  # Restore k\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 11, "result": "RE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # Invert k to check k = 0 (all |1> means original k = 0)\n    for i in range(n):\n        qc.x(k[i])\n    # Apply controlled Hadamard and phase\n    qc.h(m)  # Initial Hadamard\n    for i in range(n-1, -1, -1):  # Control chain\n        qc.cx(k[i], m)\n    # Apply phase based on m\n    qc.cz(m, m)  # Self-controlled Z to introduce (-1)^m phase\n    for i in range(n-1, -1, -1):  # Undo control chain\n        qc.cx(k[i], m)\n    qc.h(m)  # Final Hadamard to complete transformation\n    for i in range(n):\n        qc.x(k[i])  # Restore k\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 12, "result": "WA", "execution_time": "1533 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Invert k to check k = 0 (all |1> means original k = 0)\n    for i in range(n):\n        qc.x(k[i])\n    # Apply controlled Hadamard and phase\n    qc.h(m)  # Initial Hadamard\n    # Build control chain\n    for i in range(n-1, -1, -1):\n        qc.cx(k[i], m)\n    # Apply Z gate for phase (-1)^m, controlled by the chain\n    qc.z(m)  # Apply Z to introduce phase\n    for i in range(n-1, -1, -1):\n        qc.cx(k[i], m)  # Undo control chain\n    qc.h(m)  # Final Hadamard to complete transformation\n    for i in range(n):\n        qc.x(k[i])  # Restore k\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 13, "result": "WA", "execution_time": "1552 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n# Invert k to check k = 0 (all |1> means original k = 0)\n    for i in range(n):\n        qc.x(k[i])\n    # Apply controlled Hadamard and phase\n    qc.h(m)  # Initial Hadamard\n    qc.mcx(k, m)  # Multi-controlled X when k = 0\n    qc.z(m)  # Apply Z gate for (-1)^m phase\n    qc.mcx(k, m)  # Undo the control to apply conditionally\n    qc.h(m)  # Final Hadamard to complete transformation\n    for i in range(n):\n        qc.x(k[i])  # Restore k\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A88C2755F6F2E", "submission_order": 14, "result": "WA", "execution_time": "1673 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Invert k to check k = 0 (all |1> means original k = 0)\n    for i in range(n):\n        qc.x(k[i])\n    # Apply controlled transformation\n    qc.mcx(k, m)  # Control on k, target m\n    qc.h(m)  # Hadamard within control\n    qc.z(m)  # Phase flip\n    qc.h(m)  # Complete the transformation\n    qc.mcx(k, m)  # Undo the control\n    for i in range(n):\n        qc.x(k[i])  # Restore k\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A8B2B320D8663", "submission_order": 1, "result": "WA", "execution_time": "1557 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    if k==0:\n        qc.h(0)\n    else:\n        pass\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A8B2B320D8663", "submission_order": 2, "result": "WA", "execution_time": "1749 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    if k==0 and m==0:\n        qc.x(0)\n        qc.h(0)\n        \n    elif k==0 and m==1:\n        qc.h(0)\n        \n    else:\n        pass\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A8B2B320D8663", "submission_order": 3, "result": "WA", "execution_time": "1758 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.ry(np.pi / 4, m[0])\n    qc.x(k)\n    \n    qc.h(m[0])\n    qc.mcx([*k], m[0])\n    qc.h(m[0])\n    \n    qc.x(k)\n\n    qc.ry(-np.pi / 4, m[0])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A8B2B320D8663", "submission_order": 4, "result": "RE", "execution_time": "1482 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    h_gate = HGate()\n    multi_controlled_h_gate = h_gate.control(num_ctrl_qubits=n, ctrl_state='0' * n)\n    qc.append(multi_controlled_h_gate, [*k, m[0]])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A8B2B320D8663", "submission_order": 5, "result": "AC", "execution_time": "1999 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    h_gate = HGate()\n    multi_controlled_h_gate = h_gate.control(num_ctrl_qubits=n, ctrl_state='0' * n)\n    qc.append(multi_controlled_h_gate, [*k, m[0]])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 1, "result": "WA", "execution_time": "1526 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(m)\n    qc.cz(k, m)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 2, "result": "WA", "execution_time": "1662 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.ch(k, m)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 3, "result": "RE", "execution_time": "1700 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.append(HGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 4, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\nfrom qiskit.quantum_info import Statevector\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.append(HGate().control(n - 1), range(1, n + 1))\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 5, "result": "RE", "execution_time": "2108 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.append(HGate().control(n - 1), range(1, n + 1))\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 6, "result": "RE", "execution_time": "1466 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k)\n    qc.append(HGate().control(n), range(1, n + 1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 7, "result": "WA", "execution_time": "1694 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k)\n    qc.append(HGate().control(n), range(n + 1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\nfrom qiskit.quantum_info\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    for i in range(1, n + 1):\n        qc.x(i)\n    qc.append(HGate().control(n), range(n + 1))\n    for i in range(1, n + 1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 9, "result": "RE", "execution_time": "1277 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.append(HGate().control(n), k[:] + m[:])\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 10, "result": "RE", "execution_time": "1370 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    target = range()\n    qc.append(HGate().control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 11, "result": "RE", "execution_time": "1565 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), range(n+1))\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 12, "result": "RE", "execution_time": "1550 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), list(range(1, n + 1)) + [0])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 13, "result": "RE", "execution_time": "1550 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A920778DEBBB0", "submission_order": 14, "result": "AC", "execution_time": "1903 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A94B77A3F5009", "submission_order": 1, "result": "AC", "execution_time": "2188 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, XGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    for i in range(1, n + 1):\n        qc.x(i)\n    qc.append(HGate().control(n), list(range(1, n + 1)) + [0])\n    for i in range(1, n + 1):\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A96129F66D3F2", "submission_order": 1, "result": "RE", "execution_time": "1630 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.append(HGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A96129F66D3F2", "submission_order": 2, "result": "RE", "execution_time": "1455 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.append(HGate().control(n),[n,range(n)])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A96129F66D3F2", "submission_order": 3, "result": "RE", "execution_time": "1820 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    # Write your code here:\n    qc.append(HGate().control(n),k+m)\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "A96129F66D3F2", "submission_order": 4, "result": "AC", "execution_time": "2490 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    # Write your code here:\n    qc.append(HGate().control(n),k[:]+m[:])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AAA061A26196C", "submission_order": 1, "result": "WA", "execution_time": "1483 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.h(m)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AAA061A26196C", "submission_order": 2, "result": "RE", "execution_time": "1486 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(1,n+1):\n        qc.x(i)\n    qc.swap(0,n)\n    qc.append(ZGate().control(n-1), range(n))\n    qc.swap(0,n)\n    for i in range(1,n+1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AAA061A26196C", "submission_order": 3, "result": "AC", "execution_time": "1913 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(1,n+1):\n        qc.x(i)\n    qc.swap(0,n)\n    qc.append(HGate().control(n), range(n+1))\n    qc.swap(0,n)\n    for i in range(1,n+1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AABCCF1F488EA", "submission_order": 1, "result": "AC", "execution_time": "2100 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate \n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n    mcH = HGate().control(n)\n    qc.append(mcH, [*k, m[0]])\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AAD0F4E4D2A99", "submission_order": 1, "result": "RE", "execution_time": "1631 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    ch = HGATE().control(n)\n    qc.append(ch,k[:]+m[:])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AAD0F4E4D2A99", "submission_order": 2, "result": "RE", "execution_time": "1360 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    ch = HGATE().control(n)\n    qc.append(ch,k[:]+m[:])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AAD0F4E4D2A99", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGATE\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    ch = HGATE().control(n)\n    qc.append(ch,k[:]+m[:])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AAD0F4E4D2A99", "submission_order": 4, "result": "RE", "execution_time": "1658 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    h_circ.h(0)\n    h_gate = h_circ.to_gate()\n    ch_gate = h_gate.control(n)\n    qc.x(k)\n    qc.append(ch_gate,k[:]+m[:])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AAD0F4E4D2A99", "submission_order": 5, "result": "RE", "execution_time": "1450 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    h_circ = quantumCircuit(1)\n    h_circ.h(0)\n    h_gate = h_circ.to_gate()\n    ch_gate = h_gate.control(n)\n    qc.x(k)\n    qc.append(ch_gate,k[:]+m[:])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AB2EA751F9BEA", "submission_order": 1, "result": "RE", "execution_time": "1522 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    qc.x(k)\n \n    qc.append(HGate().control(n), [k, m], inplace=True)\n \n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AC9F1627437F4", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\nfrom qiskit.circuit import Gate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    for i in range(n):\n        qc.x(k[i])\n\n    qc.append(ZGate().control(n), [q for q in k] + [m[0]])\n    qc.h(m[0])\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AC9F1627437F4", "submission_order": 2, "result": "WA", "execution_time": "1885 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    for i in range(n):\n        qc.x(k[i])\n\n    qc.append(ZGate().control(n), [q for q in k] + [m[0]])\n    qc.h(m[0])\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AC9F1627437F4", "submission_order": 3, "result": "RE", "execution_time": "1557 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    if n == 1:\n        qc.x(k[0]) \n        qc.ch(k[0], m[0])\n        qc.x(k[0])\n    else:\n        for i in range(n):\n            qc.x(k[i])\n        \n        control_qubits = [k[i] for i in range(n)]\n        qc.mch(control_qubits, m[0])\n        for i in range(n):\n            qc.x(k[i])\n    \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AC9F1627437F4", "submission_order": 4, "result": "WA", "execution_time": "1631 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    for i in range(n):\n        qc.x(k[i])\n    \n    if n == 1:\n        qc.ch(k[0], m[0])\n    elif n == 2:\n        qc.ccx(k[0], k[1], m[0])\n        qc.h(m[0])\n        qc.ccx(k[0], k[1], m[0])\n        qc.h(m[0])\n    else:\n        control_qubits = [k[i] for i in range(n)]\n        qc.mcx(control_qubits, m[0])\n        qc.h(m[0])\n        qc.mcx(control_qubits, m[0])\n        qc.h(m[0])\n        \n    for i in range(n):\n        qc.x(k[i])\n    \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AC9F1627437F4", "submission_order": 5, "result": "AC", "execution_time": "1830 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    if n == 1:\n        qc.x(k[0])\n        qc.ch(k[0], m[0])\n        qc.x(k[0])\n    else:\n        h_gate = HGate()\n        controlled_h = h_gate.control(num_ctrl_qubits=n, ctrl_state='0'*n)\n        qubits = [k[i] for i in range(n)] + [m[0]]\n        qc.append(controlled_h, qubits)\n    \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACEEC18E56B5B", "submission_order": 1, "result": "RE", "execution_time": "1610 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n   \n\n    if n == 0:\n        qc.h(m[0])\n    else:\n        qc.append(HGate().control(n - 1), range(n))\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACEEC18E56B5B", "submission_order": 2, "result": "RE", "execution_time": "2121 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n   \n\n    if n == 0:\n        qc.h(m[0])\n    else:\n        qc.append(HGate().control(n - 1), k[:n-1] + [m[0]])\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACEEC18E56B5B", "submission_order": 3, "result": "AC", "execution_time": "1988 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n   \n\n    if n == 0:\n        qc.h(m[0])\n    else:\n        for i in range(n):\n            qc.x(k[i])\n        qc.append(HGate().control(n), list(k) + [m[0]])\n        for i in range(n):\n            qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    qc.h(n)\n\n    if n == 1:\n        qc.cz(0, n)\n    else:\n        qc.mcp(math.pi(), list(range(n)), n)\n    qc.h(n)\n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n    # m にHadamard\n    qc.h(m[0])\n    # k=|1...1> のときに m に制御Z\n    if n == 1:\n        qc.cz(k[0], m[0])\n    else:\n        qc.mcp(math.pi, [k[i] for i in range(n)], m[0])\n    # m にHadamard\n    qc.h(m[0])\n    # k を元に戻す\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n\n    qc.h(m[0])\n\n\n    if n == 0:\n        qc.z(m[0])  # kビットが無い場合\n    elif n == 1:\n        qc.cz(k[0], m[0])\n    else:\n        qc.mcp(math.pi, [k[i] for i in range(n)], m[0])\n\n    # mにHを作用\n    qc.h(m[0])\n\n    # kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n    \n    # 制御付きHadamard\n    if n == 1:\n        qc.ch(k[0], m[0])\n    elif n >= 2:\n        qc.h(m[0])\n        qc.mcx([k[i] for i in range(n)], m[0])\n        qc.h(m[0])\n    else:  # n==0の場合はmにHのみ\n        qc.h(m[0])\n\n    # kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n    \n    # 制御付きHadamard\n    if n == 1:\n        qc.ch(k[0], m[0])\n    elif n >= 2:\n        # n>=2の多重制御Hは分解が必要（補助ビット無しなら mcu1 + H などで近似）\n        # 例として、mビットに対して多重制御Xをはさむ\n        # ここでは簡単にmビットにHadamard+多重制御X+Hadamard\n        qc.mcx([k[i] for i in range(n)], m[0])\n        qc.x(0)\n        qc.h(m[0])\n    else:  # n==0の場合はmにHのみ\n        qc.h(m[0])\n\n    # kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n    \n    # 制御付き（k=0のときだけ）H→Z→H\n    # H\n    qc.h(m[0])\n    # 多重制御Z（符号反転、Z = P(π) = Rz(π)）\n    qc.mcz([k[i] for i in range(n)], m[0])\n    # H\n    qc.h(m[0])\n    \n    # kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 7, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n\n    # Hでmを±に分解\n    qc.h(m[0])\n    # 多重制御Xで |k=111...1⟩をmに制御X\n    if n > 0:\n        qc.mcx([k[i] for i in range(n)], m[0])\n    # Hで基底を戻す\n    qc.h(m[0])\n\n    # kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 8, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if n == 1:\n        # k[0]==1の時のみ\n        qc.ch(k[0], m[0])\n    else:\n        # n>=2: k[0]~k[n-1]すべて1の時だけm[0]にH\n        # Hadamardを2回で挟んだmcx（Toffoli拡張）でX型の符号調整も可能\n        qc.h(m[0])  # 変換\n        qc.mcx([k[i] for i in range(n)], m[0])\n        qc.h(m[0])  # 戻す\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 9, "result": "WA", "execution_time": "1645 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport math\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if n == 1:\n        # k[0]==1の時のみ\n        qc.ch(k[0], m[0])\n    else:\n        # n>=2: k[0]~k[n-1]すべて1の時だけm[0]にH\n        # Hadamardを2回で挟んだmcx（Toffoli拡張）でX型の符号調整も可能\n        qc.h(m[0])  # 変換\n        qc.mcx([k[i] for i in range(n)], m[0])\n        qc.h(m[0])  # 戻す\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 10, "result": "WA", "execution_time": "1585 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if n == 1:\n        # k[0]==1の時のみ\n        qc.ch(k[0], m[0])\n    else:\n        # n>=2: k[0]~k[n-1]すべて1の時だけm[0]にH\n        # Hadamardを2回で挟んだmcx（Toffoli拡張）でX型の符号調整も可能\n        qc.h(m[0])  # 変換\n        qc.mcx([k[i] for i in range(n)], m[0])\n        qc.h(m[0])  # 戻す\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 11, "result": "WA", "execution_time": "1586 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n    \n    # 制御付きHadamard\n    if n == 1:\n        qc.ch(k[0], m[0])\n    elif n >= 2:\n        # Hadamardで重ね合わせ\n        qc.h(m[0])\n        # 多重制御Z（符号反転）、HでX-Z-X変換して多重制御XでもOK\n        qc.mcx([k[i] for i in range(n)], m[0])\n        qc.h(m[0])\n    \n    # kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 12, "result": "WA", "execution_time": "1654 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n    \n    # 2. 多重制御Hゲート（mに対してk全部が1のときだけ作用）\n    if n == 0:\n        qc.h(m[0])  # kレジスタが無い場合\n    elif n == 1:\n        qc.ch(k[0], m[0])\n    else:\n        # HadamardでH→mcx→Hで多重制御Hを合成\n        qc.h(m[0])\n        qc.mcx([k[i] for i in range(n)], m[0])\n        qc.h(m[0])\n    \n    # 3. kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 13, "result": "WA", "execution_time": "1737 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n):\n        qc.x(k[i])\n    \n    # 2. 多重制御Hゲート（mに対してk全部が1のときだけ作用）\n    if n == 0:\n        qc.h(m[0])  # kレジスタが無い場合\n    elif n == 1:\n        qc.ch(k[0], m[0])\n    else:\n        # HadamardでH→mcx→Hで多重制御Hを合成\n\n        qc.mcx([k[i] for i in range(n)], m[0])\n        qc.x(0)\n        qc.h(m[0])\n    \n    # 3. kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "ACF96273BC5B9", "submission_order": 14, "result": "AC", "execution_time": "2301 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    anc = QuantumRegister(1, 'anc')\n    qc = QuantumCircuit(m, k, anc)\n    \n    # ancillaビットに「kがすべて0の時のみ1になる」ような多重制御X\n    if n == 1:\n        qc.x(k[0])\n        qc.cx(k[0], anc[0])\n        qc.x(k[0])\n    else:\n        for i in range(n):\n            qc.x(k[i])\n        qc.mcx([k[i] for i in range(n)], anc[0])\n        for i in range(n):\n            qc.x(k[i])\n    \n    # ancilla=1の時のみ、mビットにHadamard\n    qc.ch(anc[0], m[0])\n    \n    # ancillaを元に戻す\n    if n == 1:\n        qc.x(k[0])\n        qc.cx(k[0], anc[0])\n        qc.x(k[0])\n    else:\n        for i in range(n):\n            qc.x(k[i])\n        qc.mcx([k[i] for i in range(n)], anc[0])\n        for i in range(n):\n            qc.x(k[i])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE2FF444F05DE", "submission_order": 1, "result": "RE", "execution_time": "1732 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    qc.append(HGate().control(n - 1), range(n))\n    qc.x(k)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE2FF444F05DE", "submission_order": 2, "result": "WA", "execution_time": "1830 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    \n    qc.append(HGate().control(n), range(n+1))\n    qc.x(k)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE2FF444F05DE", "submission_order": 3, "result": "AC", "execution_time": "1971 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    \n    qc.append(HGate().control(n), list(range(1,n+1))+[0])\n    qc.x(k)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE41341724CD3", "submission_order": 1, "result": "WA", "execution_time": "1517 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(n), reversed(range(n + 1)))\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE41341724CD3", "submission_order": 2, "result": "AC", "execution_time": "2049 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    for i in range(n):\n        qc.x(k[i])\n    qc.append(HGate().control(n), reversed(range(n + 1)))\n    for i in range(n):\n        qc.x(k[i])\n \n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE4D7C683E011", "submission_order": 1, "result": "RE", "execution_time": "1560 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(k)\n\n    qc.append(ZGate().control(n + 1), list(k) + [m[0]] + [m[0]])\n    qc.append(HGate().control(n), list(k) + [m[0]])\n\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE4D7C683E011", "submission_order": 2, "result": "RE", "execution_time": "1433 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(k)\n\n    qc.append(ZGate().control(n), list(k) + [m[0]])\n    qc.append(HGate().control(n), list(k) + [m[0]])\n\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE4D7C683E011", "submission_order": 3, "result": "WA", "execution_time": "1537 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k)\n    qc.append(ZGate().control(n), list(k) + [m[0]])\n    qc.append(HGate().control(n), list(k) + [m[0]])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE4D7C683E011", "submission_order": 4, "result": "WA", "execution_time": "1592 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k)\n\n    qc.append(ZGate().control(n), list(k) + [m[0]])\n    qc.append(HGate().control(n), list(k) + [m[0]])\n\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE4D7C683E011", "submission_order": 5, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(m, k)\n\n     qc.x(k) \n    qc.append(HGate().control(n), list(k) + [m[0]]) \n    qc.x(k)  \n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE4D7C683E011", "submission_order": 6, "result": "AC", "execution_time": "2051 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k)  # flip k to detect zero state\n    qc.append(HGate().control(n), list(k) + [m[0]])  # apply H to m if k==0\n    qc.x(k)  # unflip\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AE563906D662F", "submission_order": 1, "result": "WA", "execution_time": "1434 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n# from qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    # Write your code here:\n    \n    # qc.x(0)\n        \n    for i in range(1,n+1):\n        qc.x(i)\n        \n    qc.mcx(control_qubits=[i for i in range(1,n+1)], target_qubit=0)\n\n    qc.h(0)\n\n    qc.mcx(control_qubits=[i for i in range(1,n+1)], target_qubit=0)\n \n    for i in range(1,n+1):\n        qc.x(i)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A2", "user": "AE563906D662F", "submission_order": 2, "result": "WA", "execution_time": "1608 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n# from qiskit.quantum_info import Statevector\n# from qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    # Write your code here:\n    \n    # qc.x(0)\n        \n    for i in range(1,n+1):\n        qc.x(i)\n        \n    qc.mcx(control_qubits=[i for i in range(1,n+1)], target_qubit=0)\n\n    qc.h(0)\n    qc.z(0)\n\n    # qc.mcx(control_qubits=[i for i in range(1,n+1)], target_qubit=0)\n \n    for i in range(1,n+1):\n        qc.x(i)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A2", "user": "AE563906D662F", "submission_order": 3, "result": "AC", "execution_time": "1969 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library.standard_gates import HGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    # Write your code here:\n    \n    # qc.x(0)\n        \n    for i in range(1,n+1):\n        qc.x(i)\n        \n    L=[i for i in range(1,n+1)]\n    L.append(0)\n    qc.append(HGate().control(n),L)\n \n \n    for i in range(1,n+1):\n        qc.x(i)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 1, "result": "RE", "execution_time": "1852 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    \n    qc.x(k)\n\n    qc.mch(k, 0)\n    qc.x(k)\n\n\n\n\n\n    \n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 2, "result": "WA", "execution_time": "1456 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    \n    \n    qc.h(0)\n    \n\n\n\n\n    \n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 3, "result": "RE", "execution_time": "1748 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(num_ctrl_qubits=n), range(1, n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 4, "result": "RE", "execution_time": "1539 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(n), k)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 5, "result": "RE", "execution_time": "1459 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(n), k)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 6, "result": "RE", "execution_time": "1371 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(n-1), k)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 7, "result": "RE", "execution_time": "1576 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(n+1),)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 8, "result": "RE", "execution_time": "1479 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 9, "result": "RE", "execution_time": "1307 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(k+m))\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 10, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(HGate().control(k+m))\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 11, "result": "RE", "execution_time": "1586 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(qiskit.circuit.library.HGate().control(k+m))\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 12, "result": "RE", "execution_time": "1321 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.append(qiskit.circuit.library.HGate().control(n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 13, "result": "RE", "execution_time": "1501 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    h_gate = qiskit.circuit.library.standard_gates.h.HGate()\n    ch_gate = h_gate.control(num_ctrl_qubits=n)\n\n    qc.append(chgate, [*k, m[0]])\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 14, "result": "RE", "execution_time": "1639 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    h_gate = qiskit.circuit.library.standard_gates.h.HGate()\n    ch_gate = h_gate.control(num_ctrl_qubits=n)\n\n    qc.append(ch_gate, [*k, m[0]])\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 15, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport qiskit\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    h_gate = qiskit.circuit.library.standard_gates.h.HGate()\n    ch_gate = h_gate.control(num_ctrl_qubits=n)\n\n    qc.append(ch_gate, [*k, m[0]])\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 16, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import Gate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    h_gate = qiskit.circuit.library.standard_gates.h.HGate()\n    ch_gate = h_gate.control(num_ctrl_qubits=n)\n\n    qc.append(ch_gate, [*k, m[0]])\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 17, "result": "RE", "execution_time": "1380 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    h_gate = qiskit.circuit.library.standard_gates.h.HGate()\n    ch_gate = h_gate.control(num_ctrl_qubits=n)\n\n    qc.append(HGate().control(n), [*k, m[0]])\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 18, "result": "WA", "execution_time": "1815 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n\n\n    qc.append(HGate().control(n), [*k, m[0]])\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AEF15BAA21FBE", "submission_order": 19, "result": "AC", "execution_time": "2060 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(k)\n    qc.append(HGate().control(n), [*k, m[0]])\n    qc.x(k)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF2F34E5BEB0A", "submission_order": 1, "result": "RE", "execution_time": "1495 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(0)\n    qc.compose(HGate().control(n),[*k, *m])\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF2F34E5BEB0A", "submission_order": 2, "result": "RE", "execution_time": "1660 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(0)\n    qc.compose(HGate().control(n),[*k, m[0]], inplace=True)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF2F34E5BEB0A", "submission_order": 3, "result": "RE", "execution_time": "1575 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.compose(HGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF2F34E5BEB0A", "submission_order": 4, "result": "AC", "execution_time": "2038 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.compose(HGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF52C677561F6", "submission_order": 1, "result": "RE", "execution_time": "1395 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.mh(k, m)\n\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF52C677561F6", "submission_order": 2, "result": "RE", "execution_time": "1479 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.swap(0, n)\n    qc.append(HGate.control(n), range(n + 1))\n    qc.swap(n, 0)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF52C677561F6", "submission_order": 3, "result": "WA", "execution_time": "1651 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here\n\n    qc.append(HGate().control(n), list(range(1, n+1)) + [0])\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF52C677561F6", "submission_order": 4, "result": "RE", "execution_time": "1435 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here\n    for i in range(1, n + 1):\n        qc.x[i]\n    qc.append(HGate().control(n), list(range(1, n+1)) + [0])\n    \n    for i in range(1, n + 1):\n        qc.x[i]\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AF52C677561F6", "submission_order": 5, "result": "AC", "execution_time": "1863 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here\n    for i in range(1, n + 1):\n        qc.x(i)\n\n    qc.append(HGate().control(n), list(range(1, n+1)) + [0])\n    \n    for i in range(1, n + 1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 1, "result": "WA", "execution_time": "1668 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k == 0:\n        qc.h(m)\n        if m == 1:\n            qc.z(k)\n        else:\n            qc.i(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 2, "result": "WA", "execution_time": "1924 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k == 0:\n        qc.h(m)\n        if m == 1:\n            qc.z(k)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 3, "result": "WA", "execution_time": "1544 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k == 0:\n        qc.h(m)\n        qc.append(ZGate().control(n - 1), range(n))\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 4, "result": "WA", "execution_time": "1605 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k == 0:\n        qc.h(m)\n        qc.append(ZGate().control(m), range(n))\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 5, "result": "WA", "execution_time": "1554 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k == 0:\n        qc.h(m)\n        qc.append(ZGate().control(m), range(k))\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 6, "result": "WA", "execution_time": "1575 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k == 0:\n        qc.h(m)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 7, "result": "WA", "execution_time": "1618 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k == 0:\n        qc.h(m)\n        if m == 1:\n            qc.z(m)\n        qc.append(ZGate().control(n-1), range(n))\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 8, "result": "WA", "execution_time": "1587 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    if k == 0:\n        qc.h(0)\n    return qc\n'''"}
{"problem": "QPC005_A2", "user": "AFBB2132D8EC2", "submission_order": 9, "result": "WA", "execution_time": "1608 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A152A6596C85E", "submission_order": 1, "result": "DLE", "execution_time": "1458 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(1,n+1):\n        qc.x(i)\n    qc.swap(0,n)\n    qc.append(XGate().control(n), range(n+1))\n    qc.swap(0,n)\n    for i in range(n+1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A152A6596C85E", "submission_order": 2, "result": "RE", "execution_time": "1568 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(1,n+1):\n        qc.x(i)\n    #qc.swap(0,n)\n    qc.append(XGate().control(0), range(n+1))\n    #qc.swap(0,n)\n    for i in range(n+1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A2A70302654B9", "submission_order": 1, "result": "WA", "execution_time": "1760 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n    qc.x(k)\n    qc.compose(HGate().control(len(k)),[*k, *m])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A2A70302654B9", "submission_order": 2, "result": "WA", "execution_time": "2118 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, *m])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A2A70302654B9", "submission_order": 3, "result": "AC", "execution_time": "2133 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A2E6C1149499F", "submission_order": 1, "result": "RE", "execution_time": "1467 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit.circuit.library.standard_gates import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    mch_gate = XGate().control(n)\n    qc.append(mch_gate, range(n, -1, -1))\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A2E6C1149499F", "submission_order": 2, "result": "WA", "execution_time": "1549 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    mch_gate = XGate().control(n)\n    qc.append(mch_gate, range(n, -1, -1))\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A45616F508BA5", "submission_order": 1, "result": "AC", "execution_time": "2093 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(i for i in k)\n    qc.x(m[0])\n    qc.append(XGate().control(n), list(k) + [m[0]])\n    qc.x(i for i in k)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A50A442372A23", "submission_order": 1, "result": "AC", "execution_time": "2058 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), list(range(1, n+1))+[0])\n    qc.x(k)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A560475986889", "submission_order": 1, "result": "WA", "execution_time": "1629 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # qc.h(m)\n    # qc.h(k)\n\n    for i in range(1, n):\n        if k[i] == 0:\n            qc.x(k[i])\n    control = [i+1 for i in range(n)]\n    qc.append(XGate().control(n), [*control, 0])\n    for i in range(1, n):\n        if k[i] == 0:\n            qc.x(k[i])\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A560475986889", "submission_order": 2, "result": "WA", "execution_time": "1587 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    # qc.h(m)\n    # qc.h(k)\n\n    control = [i+1 for i in range(n)]\n    qc.append(XGate().control(n), [*control, 0])\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A58910C23A19D", "submission_order": 1, "result": "AC", "execution_time": "1944 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    x0h = XGate().control(n, ctrl_state=0)\n    qc.append(x0h, list(range(1, n + 1)) + [0])\n    qc.x(0)\n\n    return qc\n\n\ndef main():\n    print(solve(1))\n    print(solve(2))\n    print(solve(3))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A3", "user": "A58D628DA1484", "submission_order": 1, "result": "AC", "execution_time": "1811 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate, ZGate, MCXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    if n == 1:\n        qc.cx(k[0], m[0])\n    elif n == 2:\n        qc.cx(k[0], m[0])    \n        qc.cx(k[1], m[0])      \n        qc.ccx(k[0], k[1], m[0]) \n    else:\n        for i in range(n):\n            qc.x(k[i])\n        \n        mcx_gate = MCXGate(num_ctrl_qubits=n)\n        qc.append(mcx_gate, [k[i] for i in range(n)] + [m[0]])\n        for i in range(n):\n            qc.x(k[i])\n        \n        qc.x(m[0])\n    \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A593934A3C923", "submission_order": 1, "result": "WA", "execution_time": "1795 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), k[:] + [m[0]])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A593934A3C923", "submission_order": 2, "result": "AC", "execution_time": "2218 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m[0])\n    qc.x(k)\n    qc.append(XGate().control(n), k[:] + [m[0]])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5BC6C9CADAD6", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n   \n\n    if n == 0:\n        pass\n    else:\n       for i in range(n):\n            qc.x(k[i])\n        \n        if n == 1:\n            qc.cx(k[0], m[0])\n        else:\n            qc.append(HGate().control(n), list(k) + [m[0]])\n        for i in range(n):\n            qc.x(k[i])\n        qc.x(m[0]) \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5BC6C9CADAD6", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n   \n\n    if n == 0:\n        pass\n    else:\n       for i in range(n):\n            qc.x(k[i])\n        \n        if n == 1:\n            qc.cx(k[0], m[0])\n        else:\n            qc.append(XGate().control(n), list(k) + [m[0]])\n        for i in range(n):\n            qc.x(k[i])\n        qc.x(m[0])   \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5BC6C9CADAD6", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n   \n\n    if n == 0:\n        pass\n    else:\n       for i in range(n):\n            qc.x(k[i])\n        \n        if n == 1:\n            qc.cx(k[0], m[0])\n        else:\n            qc.append(XGate().control(n), list(k) + [m[0]])\n        for i in range(n):\n            qc.x(k[i])\n        qc.x(m[0])   \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5BC6C9CADAD6", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    if n == 0:\n        pass\n    else:\n       for i in range(n):\n            qc.x(k[i])\n        if n == 1:\n            qc.cx(k[0], m[0])\n        else:\n            qc.append(XGate().control(n), list(k) + [m[0]])\n        for i in range(n):\n            qc.x(k[i])\n        qc.x(m[0])   \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5BC6C9CADAD6", "submission_order": 5, "result": "AC", "execution_time": "2029 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m[0])\n    \n    if n == 0:\n        qc.x(m[0])\n    else:\n        controlled_x_gate = XGate().control(num_ctrl_qubits=n, ctrl_state='0'*n)\n        qc.append(controlled_x_gate, list(k) + [m[0]])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5C5A216927C4", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n\n    qc.x(k)\n    qc.(XGate().append.control(n), list(k) + [m[0]])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5C5A216927C4", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n\n    qc.x(k)\n    qc.(XGate().append.control(n), list(k) + [m[0]])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5C5A216927C4", "submission_order": 3, "result": "AC", "execution_time": "2254 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n\n    qc.x(k)\n    qc.append(XGate().control(n), list(k) + [m[0]])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5F80364B04ED", "submission_order": 1, "result": "WA", "execution_time": "1615 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, XGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    for i in range(1, n + 1):\n        qc.x(i)\n    qc.append(XGate().control(n), list(range(1, n + 1)) + [0])\n    for i in range(1, n + 1):\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A5F80364B04ED", "submission_order": 2, "result": "AC", "execution_time": "2014 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, XGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(0)\n    for i in range(1, n + 1):\n        qc.x(i)\n    qc.append(XGate().control(n), list(range(1, n + 1)) + [0])\n    for i in range(1, n + 1):\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A64AD47461307", "submission_order": 1, "result": "AC", "execution_time": "2198 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import XGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(m)\n    qc.x(k)\n    qc.append(XGate().control(n), reversed(range(0, n + 1)))\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A6FE225D2594B", "submission_order": 1, "result": "WA", "execution_time": "1642 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    for i in range(n):\n        qc.x(k[i])\n    qc.append(XGate().control(n), reversed(range(n + 1)))\n    for i in range(n):\n        qc.x(k[i])\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A6FE225D2594B", "submission_order": 2, "result": "AC", "execution_time": "1952 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    for i in range(n):\n        qc.x(k[i])\n    qc.append(XGate().control(n), reversed(range(n + 1)))\n    for i in range(n):\n        qc.x(k[i])\n    qc.x(m[0])\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A74213C511CE0", "submission_order": 1, "result": "WA", "execution_time": "1487 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n+1):\n        qc.x(i)\n    qc.mcx(list(range(1, n + 1)), 0)\n\n    for i in range(n + 1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A74213C511CE0", "submission_order": 2, "result": "AC", "execution_time": "1948 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n+1):\n        qc.x(i)\n    qc.mcx(list(range(1, n + 1)), 0)\n\n    for i in range(1, n + 1):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A75263BAB61DA", "submission_order": 1, "result": "AC", "execution_time": "1869 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    \n    \n    qc.x(0)\n    \n    for i in range(1,n+1):\n        qc.x(i)\n        \n    L=[i for i in range(1,n+1)]\n    L.append(0)\n    qc.append(XGate().control(n),L)\n \n    for i in range(1,n+1):\n        qc.x(i)\n        \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A3", "user": "A7C695D93D267", "submission_order": 1, "result": "WA", "execution_time": "1643 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    \n    qc.append(XGate().control(n), list(range(1,n+1))+[0])\n    qc.x(k)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A7C695D93D267", "submission_order": 2, "result": "AC", "execution_time": "2068 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(0)\n    qc.x(k)\n    \n    qc.append(XGate().control(n), list(range(1,n+1))+[0])\n    qc.x(k)\n\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A80513CC7B67A", "submission_order": 1, "result": "WA", "execution_time": "1784 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.mcx(k,m)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A80513CC7B67A", "submission_order": 2, "result": "AC", "execution_time": "2044 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.mcx(k,m)\n    qc.x(k)\n    qc.x(m)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 1, "result": "WA", "execution_time": "1492 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k) \n    qc.append(XGate().control(n), list(k) + [m[0]])  \n    qc.x(k)  \n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 2, "result": "WA", "execution_time": "1434 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(m, k)\n\n    qc.x(k) \n    qc.mcx(list(k), m[0])\n    qc.x(k)  \n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 3, "result": "WA", "execution_time": "1916 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n\n\n    qc.x(k)\n    qc.append(XGate().control(n), list(k) + [m[0]])\n    qc.x(k)\n    qc.x(m[0])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 4, "result": "WA", "execution_time": "1861 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n\n\n    qc.x(k)\n    qc.append(XGate().control(n), list(k) + [m[0]])\n    qc.x(k)\n    # qc.x(m[0])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 5, "result": "WA", "execution_time": "1687 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n\n\n    qc.x(m[0])\n    qc.x(k)\n    qc.mcx(k, m[0])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 6, "result": "WA", "execution_time": "1826 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n\n\n    for i in range(n):\n        qc.cx(k[i], m[0])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 7, "result": "WA", "execution_time": "1712 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n\n\n    qc.x(m[0])\n\n    qc.x(k)\n\n    qc.mcx(k, m[0])\n    \n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 8, "result": "WA", "execution_time": "1710 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n\n\n    for i in range(n):\n        qc.cx(k[i], m[0])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 9, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n=\n    for i in range(n):\n        qc.x(k[i])\n\n   \n    qc.h(m[0])\n    qc.append(ZGate().control(n), [k[i] for i in range(n)] + [m[0]])\n    qc.h(m[0])\n\n\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 10, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate, ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n=\n    for i in range(n):\n        qc.x(k[i])\n\n   \n    qc.h(m[0])\n    qc.append(ZGate().control(n), [k[i] for i in range(n)] + [m[0]])\n    qc.h(m[0])\n\n\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A86D768DAE597", "submission_order": 11, "result": "WA", "execution_time": "1752 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m = QuantumRegister(1, 'm')\n    k = QuantumRegister(n, 'k')\n    qc = QuantumCircuit(k, m)\n\n    for i in range(n):\n        qc.x(k[i])\n\n    qc.h(m[0])\n    qc.append(ZGate().control(n), [k[i] for i in range(n)] + [m[0]])\n    qc.h(m[0])\n\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A93FAEEF9A500", "submission_order": 1, "result": "AC", "execution_time": "1936 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.x(m)\n    qc.x(k)\n    qc.append(XGate().control(n), [*k, *m])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A95429CFF06C1", "submission_order": 1, "result": "AC", "execution_time": "2027 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    for i in range(n+1):\n        qc.x(i)\n\n    mc_h = XGate().control(n)\n\n    qubits = list(range(n, 0, -1)) + [0] \n    qc.append(mc_h, qubits)\n\n    for i in range(n):\n        qc.x(i + 1)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A97208DB47939", "submission_order": 1, "result": "AC", "execution_time": "1851 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    qc.x(m[0])\n    qc.x(k)\n    qc.mcx(k, m[0])\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A97C267145786", "submission_order": 1, "result": "RE", "execution_time": "1471 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    if n == 1:\n        qc.cx(k[0], m[0])\n    else:\n        # NOT(k)を作って、全ビット0のとき以外反転\n        for i in range(n):\n            qc.x(k[i])\n        qc.x(m[0]).c_if(qc.cregs[0], 0)  # 古典条件付きではなく下でANDで\n        qc.mcx([k[i] for i in range(n)], m[0])  # 多重制御X\n        for i in range(n):\n            qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A97C267145786", "submission_order": 2, "result": "WA", "execution_time": "1795 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    for i in range(n):\n        qc.x(k[i])\n\n    # 多重制御X（kが全て1→m反転、つまり元のkが全て0以外）\n    qc.mcx([k[i] for i in range(n)], m[0])\n\n    # kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A97C267145786", "submission_order": 3, "result": "WA", "execution_time": "1629 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    if n > 2:\n        anc = QuantumRegister(n-2, 'anc')\n        qc = QuantumCircuit(m, k, anc)\n        # k[0]~k[n-1]がすべて1のとき m[0] にX\n        qc.mcx([k[i] for i in range(n)], m[0], ancilla_qubits=anc, mode='v-chain')\n    else:\n        qc = QuantumCircuit(m, k)\n        qc.mcx([k[i] for i in range(n)], m[0])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "A97C267145786", "submission_order": 4, "result": "AC", "execution_time": "2164 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n\n    qc.x(m[0])\n\n    # k全てにXをかけて「全て1」を「全て0」に写す\n    for i in range(n):\n        qc.x(k[i])\n\n    # 多重制御X（kが全て1→m反転、つまり元のkが全て0以外）\n    qc.mcx([k[i] for i in range(n)], m[0])\n\n    # kを元に戻す\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AC117705631FC", "submission_order": 1, "result": "DLE", "execution_time": "1590 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # qc.x(k)\n    # qc.x(m)\n\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.x(k)\n    qc.z(m)\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.x(k)\n    qc.x(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AC117705631FC", "submission_order": 2, "result": "DLE", "execution_time": "1853 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n    # qc.x(k)\n    # qc.x(m)\n\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.z(m)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.x(k)\n    qc.x(m)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AC117705631FC", "submission_order": 3, "result": "WA", "execution_time": "1565 ms", "memory": "143 MiB", "code": "'''python\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import RYGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    qc.append(RYGate(-pi / 2).control(n), k[:] + m[:])\n    qc.z(m)\n    qc.append(RYGate(-pi / 2).control(n), k[:] + m[:])\n    qc.x(m)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AC117705631FC", "submission_order": 4, "result": "WA", "execution_time": "1586 ms", "memory": "143 MiB", "code": "'''python\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n\n\n    qc.append(HGate().control(n, ctrl_state=\"0\"*n), k[:] + m[:])\n    qc.z(m)\n    qc.append(HGate().control(n, ctrl_state=\"0\"*n), k[:] + m[:])\n    qc.x(m)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AC78CE99676C6", "submission_order": 1, "result": "AC", "execution_time": "1948 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m[0])\n    for i in range(n):\n        qc.x(k[i])\n    qc.mcx([*k], m[0])\n    for i in range(n):\n        qc.x(k[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AD21398C33D90", "submission_order": 1, "result": "AC", "execution_time": "1733 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(range(n + 1))\n    qc.mcx(k, m)\n    qc.x(k)\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AEC556B642C21", "submission_order": 1, "result": "RE", "execution_time": "1385 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    # Write your code here:\n    qc.append(CXGate().control(n),k[:]+m[:])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AEC556B642C21", "submission_order": 2, "result": "WA", "execution_time": "1534 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    # Write your code here:\n    qc.append(XGate().control(n),k[:]+m[:])\n    qc.x(k)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AEC556B642C21", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import MXGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    # Write your code here:\n    qc.append(XGate().control(n),k[:]+m[:])\n    qc.x(k)\n    qc.x(m)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AEC556B642C21", "submission_order": 4, "result": "AC", "execution_time": "1945 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.x(k)\n    # Write your code here:\n    qc.append(XGate().control(n),k[:]+m[:])\n    qc.x(k)\n    qc.x(m)\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 1, "result": "RE", "execution_time": "1477 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n \n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 2, "result": "WA", "execution_time": "1503 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), k[:] + m[:])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 3, "result": "WA", "execution_time": "1740 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(HGate().control(n), list(range(1, n + 1)) + [0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 4, "result": "RE", "execution_time": "1483 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), list(range(1, n + 1)) + [0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 5, "result": "WA", "execution_time": "1488 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), list(range(1, n + 1)) + [0])\n    qc.x(k)\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 6, "result": "WA", "execution_time": "1564 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n \ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.append(XGate().control(n), list(range(1, n + 1)) + [0])\n \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 7, "result": "RE", "execution_time": "1562 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), m[:], k[:])\n    qc.x(k)\n    qc.x(m)\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 8, "result": "RE", "execution_time": "1426 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), m[:], k[:])\n    qc.x(k)\n    qc.x(m)\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 9, "result": "RE", "execution_time": "1447 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), k[:] + m[:])\n    qc.x(k)\n    qc.x(m)\n'''"}
{"problem": "QPC005_A3", "user": "AF08F11F4F2B3", "submission_order": 10, "result": "AC", "execution_time": "2017 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(k)\n    qc.append(XGate().control(n), k[:] + m[:])\n    qc.x(range(n+1))\n\n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF46ADF82CE78", "submission_order": 1, "result": "RE", "execution_time": "1467 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    for i in range(n):\n        controlled_cx = CXGate().control(n, ctrl_state='0' * n)\n        qc.append(controlled_cx, k[:] + [m[0]] + [k[i]])\n    \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF46ADF82CE78", "submission_order": 2, "result": "WA", "execution_time": "1715 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import CXGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    for i in range(1,n+1):\n        qc.x(i)\n    # k/n = 1の場合（すべてのkビットが1）にmを反転\n    if n == 1:\n        qc.cx(k[0], m[0])\n    else:\n        qc.mcx(k[:], m[0])\n    for i in range(1,n+1):\n        qc.x(i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF46ADF82CE78", "submission_order": 3, "result": "WA", "execution_time": "1741 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    for i in range(n):\n        qc.x(k[i])\n    \n    qc.mcx(k, m[0])\n    \n    for i in range(n):\n        qc.x(k[i])\n    \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AF46ADF82CE78", "submission_order": 4, "result": "AC", "execution_time": "1798 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    \n    for i in range(n):\n        qc.x(k[i])\n    \n    qc.mcx(k, m[0])\n    \n    for i in range(n):\n        qc.x(k[i])\n    \n    qc.x(m[0])\n    \n    return qc\n'''"}
{"problem": "QPC005_A3", "user": "AFA91A992947E", "submission_order": 1, "result": "AC", "execution_time": "1800 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    qc.append(XGate(), [m[0]])\n    qc.append(XGate().control(n, ctrl_state='0'*n), k[:] + [m[0]])\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A05D34C0F736F", "submission_order": 1, "result": "WA", "execution_time": "1951 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A05D34C0F736F", "submission_order": 2, "result": "WA", "execution_time": "1927 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in reversed(range(n - 1)):\n        qc.cx(i, i + 1)\n \n    for i in reversed(range(n - 1)):\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A05D34C0F736F", "submission_order": 3, "result": "WA", "execution_time": "1683 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.cx(0, n)\n    qc.cx(n, 0)\n    for i in reversed(range(n - 2)):\n        qc.cx(i, i + 1)\n \n    for i in reversed(range(n - 2)):\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A0A03355792D9", "submission_order": 1, "result": "DLE", "execution_time": "1798 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n, 0, -1):\n        qc.cx(i, i-1)\n        qc.cx(i-1, i)\n        qc.cx(i, i-1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A0A03355792D9", "submission_order": 2, "result": "AC", "execution_time": "1957 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    memo = list(range(n + 1))\n    while len(memo) >= 2:\n        memo2 = []\n        while len(memo) >= 2:\n            i = memo.pop(0)\n            j = memo.pop(0)\n            qc.swap(i, j)\n            memo2.append(i)\n        memo2 += memo\n        memo = memo2\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A157E1904B000", "submission_order": 1, "result": "WA", "execution_time": "1900 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n    for i in range(n):\n        qc.cx(i, n)\n    \n    for i in range(n):\n        qc.cx(n, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A157E1904B000", "submission_order": 2, "result": "WA", "execution_time": "1754 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    for i in range((n + 1) // 2):\n        qc.swap(i, n - i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A157E1904B000", "submission_order": 3, "result": "DLE", "execution_time": "1571 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(n):\n        qc.swap(n - i - 1, n - i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A157E1904B000", "submission_order": 4, "result": "RE", "execution_time": "1531 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i, i + n)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A157E1904B000", "submission_order": 5, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1, name=f\"Controlled Increment(n={n})\")\n    \n    k_qubits = list(range(n))\n    m_qubit = n\n\n    qc.append(QFT(n, do_swaps=True, little_endian=True), k_qubits)\n\n    for i in range(n):\n        angle = np.pi / (2**i)\n        qc.cp(angle, m_qubit, k_qubits[n-1-i])\n\n    qc.append(QFT(n, do_swaps=True, little_endian=True).inverse(), k_qubits)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A157E1904B000", "submission_order": 6, "result": "UGE", "execution_time": "1529 ms", "memory": "140 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qft_builder_qc = QuantumCircuit(n, name='QFT')\n    for i in range(n - 1, -1, -1):\n        qft_builder_qc.h(i)\n        for j in range(i - 1, -1, -1):\n            angle = np.pi / (2**(i - j))\n            qft_builder_qc.cp(angle, j, i)\n    for i in range(n // 2):\n        qft_builder_qc.swap(i, n - 1 - i)\n\n    qft_gate = qft_builder_qc.to_gate(label='QFT')\n    iqft_gate = qft_gate.inverse()\n    iqft_gate.label = 'IQFT'\n\n    qc = QuantumCircuit(n + 1)\n    k_qubits = list(range(n))\n    m_qubit = n\n\n    qc.append(qft_gate, k_qubits)\n\n    for i in range(n):\n        angle = 2 * np.pi / (2**(i + 1))\n        qc.cp(angle, m_qubit, k_qubits[i])\n\n    qc.append(iqft_gate, k_qubits)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A20BEF48352EA", "submission_order": 1, "result": "DLE", "execution_time": "1463 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n    if n == 1:\n        qc.swap(0, 1)\n    elif n == 2:\n        qc.swap(2, 1)  \n        qc.swap(1, 0)  \n    elif n == 3:\n        qc.swap(3, 2)  \n        qc.swap(2, 1)  \n        qc.swap(1, 0)  \n    elif n == 4:\n        qc.swap(4, 3)  \n        qc.swap(3, 2)  \n        qc.swap(2, 1)  \n        qc.swap(1, 0)  \n    else:\n        for i in range(n):\n            qc.swap(n - i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A2669E2362D2A", "submission_order": 1, "result": "DLE", "execution_time": "1559 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n):\n        qc.swap(i, n)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A308D36EDB3A6", "submission_order": 1, "result": "WA", "execution_time": "1651 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for layer in range(4):\n        for i in range(layer % 2, n, 2):\n            qc.swap(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A308D36EDB3A6", "submission_order": 2, "result": "WA", "execution_time": "1655 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range((n + 1) // 2):\n        qc.swap(i, n - i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A308D36EDB3A6", "submission_order": 3, "result": "WA", "execution_time": "1669 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for layer in range(4):\n        for i in range(layer % 2, n, 2):\n            qc.swap(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A450E8F7CE3E0", "submission_order": 1, "result": "WA", "execution_time": "2109 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(n):\n        qc.swap(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A450E8F7CE3E0", "submission_order": 2, "result": "AC", "execution_time": "1995 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(0, n, 2):\n        qc.swap(i, i + 1)\n\n    for i in range(0, n - 1, 4):\n        qc.swap(i, i + 2)\n\n    for i in range(0, n - 3, 8):\n        qc.swap(i, i + 4)\n\n    for i in range(0, n - 7, 16):\n        qc.swap(i, i + 8)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A4826F9B0ECA8", "submission_order": 1, "result": "AC", "execution_time": "2302 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate\n\ndef solve(n: int) -> QuantumCircuit:\n    n += 1\n    qc = QuantumCircuit(n)\n\n    def shift_r(l: int, r: int) -> None:\n        if r - l == 1:\n            return\n        m = (l + r) >> 1\n        qc.swap(m - 1, r - 1)\n        shift_r(l, m)\n        shift_r(m, r)\n    shift_r(0, n)\n \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A4D9C4BDF1EF2", "submission_order": 1, "result": "RE", "execution_time": "1585 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate\n\n\ndef swap(a: int, b: int, n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.cx(a,b)\n    qc.cx(b,a)\n    qc.cx(a,b)\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    for i in range(n - 1):\n        swapqc = swap(i, i+1, n + 1)\n        qc.append(swapqc, range(n + 1))\n    qc.append(swap(n - 1, 0, n + 1), range(n + 1))\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A4D9C4BDF1EF2", "submission_order": 2, "result": "WA", "execution_time": "1574 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:  \n    qc = QuantumCircuit(n + 1)  \n \n    for i in reversed(range(n)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A6B60CCEA46FD", "submission_order": 1, "result": "WA", "execution_time": "1871 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n,0,-1):\n        #qc.cx(i,i-1)\n        qc.cx(i-1,i)\n        qc.cx(i,i-1)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A6B60CCEA46FD", "submission_order": 2, "result": "WA", "execution_time": "1831 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    n1 = (n+1) // 2\n    for i in range(n1):\n        qc.swap(i, n - i)\n    n2 = n // 2\n    for i in range(n2):\n        qc.swap(i, n -1 - i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A6B60CCEA46FD", "submission_order": 3, "result": "AC", "execution_time": "1742 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    n1 = (n+1) // 2\n    for i in range(n1):\n        qc.swap(i, n - i)\n    n2 = n // 2\n    for i in range(n2):\n        qc.swap(i+1, n - i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A80B1DDDC70F1", "submission_order": 1, "result": "WA", "execution_time": "1523 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n) -> QuantumCircuit:\n    input, anc = QuantumRegister(n + 1), QuantumRegister(n + 1)\n    qc = QuantumCircuit(input, anc)\n\n    def d2swap(x, y):\n        qc.append(XXPlusYYGate(np.pi), [x, y])\n        qc.append(RZZGate(np.pi / 2), [x, y])\n\n    for i in range(n + 1):\n        d2swap(input[i], anc[i])\n\n    d2swap(anc[0], input[-1])\n    for i in range(n):\n        d2swap(input[i], anc[i + 1])\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A80B1DDDC70F1", "submission_order": 2, "result": "DLE", "execution_time": "1456 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n) -> QuantumCircuit:\n    input, anc = QuantumRegister(n + 1), QuantumRegister(n + 1)\n    qc = QuantumCircuit(input, anc)\n\n    def d2swap(x, y):\n        qc.append(XXPlusYYGate(np.pi), [x, y])\n        qc.append(RZZGate(np.pi / 2), [x, y])\n\n    for i in range(n + 1):\n        d2swap(input[i], anc[i])\n\n    d2swap(anc[-1], input[0])\n    for i in range(n):\n        d2swap(input[i - 1], anc[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A80B1DDDC70F1", "submission_order": 3, "result": "AC", "execution_time": "3000 ms", "memory": "275 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n) -> QuantumCircuit:\n    input, anc = QuantumRegister(n + 1), QuantumRegister(n + 1)\n    qc = QuantumCircuit(input, anc)\n\n    def d2swap(x, y):\n        qc.append(XXPlusYYGate(np.pi), [x, y])\n        qc.append(RZZGate(np.pi / 2), [x, y])\n\n    for i in range(n + 1):\n        d2swap(input[i], anc[i])\n\n    d2swap(anc[-1], input[0])\n    for i in range(n):\n        d2swap(input[i + 1], anc[i])\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8670C104130E", "submission_order": 1, "result": "RE", "execution_time": "1562 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    if n > 0:\n        qc.swap(k[0], m[0])\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8670C104130E", "submission_order": 2, "result": "RE", "execution_time": "1572 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    # Write your code here:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    if n > 0:\n        qc.swap(k[0], m[0])\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8670C104130E", "submission_order": 3, "result": "WA", "execution_time": "1721 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    # Write your code here:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    if n > 0:\n        qc.swap(k[0], m[0])\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8670C104130E", "submission_order": 4, "result": "DLE", "execution_time": "1417 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\n\n\ndef solve(n: int) -> QuantumCircuit:\n    # Write your code here:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    if n > 0:\n       for i in range(n):\n        qc.swap(k[i], m[0])\n\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8670C104130E", "submission_order": 5, "result": "DLE", "execution_time": "1615 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    for i in range(n):\n        qc.swap(i, n)  # n番目のビットが |m⟩\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8670C104130E", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n      qc.x(range(n + 1))  # 全ビットを反転\n    qc.mcz(list(range(n)), n)  #\n    qc.x(range(n + 1))  # 元に戻す\n    \n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 1, "result": "WA", "execution_time": "1785 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 2, "result": "WA", "execution_time": "1615 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n):\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 3, "result": "RE", "execution_time": "1457 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n+1):\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 4, "result": "RE", "execution_time": "1696 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(1,n+1):\n        qc.cx(i + 1, i)\n        qc.cx(i, i + 1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 5, "result": "WA", "execution_time": "1613 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n):\n        qc.swap(i,i+1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 6, "result": "DLE", "execution_time": "1586 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(n,0,-1):\n        qc.swap(i,i-1)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 7, "result": "WA", "execution_time": "1553 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(4):\n        for j in range(0, n-2**i, 2 * 2**i):\n            qc.swap(i,j+2**i)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 8, "result": "WA", "execution_time": "1775 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    m = n+1\n    # Write your code here:\n    for i in reversed(range(4)):\n        for j in reversed(range(0, m-2**i, 2 * 2**i)):\n            qc.swap(i,j+2**i)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 9, "result": "WA", "execution_time": "1704 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    m = n+1\n    # Write your code here:\n    for i in range(4):\n        for j in range(0, m-2**i, 2 * 2**i):\n            qc.swap(i,j+2**i)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 10, "result": "RE", "execution_time": "1574 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    m = n+1\n    # Write your code here:\n    for i in range(m//2):\n        qc.swap(i, n-i-1)\n    for i in range(m//2 - 1):\n        qc.swap(i+1, n-i-1)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 11, "result": "RE", "execution_time": "1479 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    m = n+1\n    # Write your code here:\n    for i in range(m//2):\n        qc.swap(i, n-i-1)\n    for i in range(m//2 - 1):\n        qc.swap(i+1, n-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 12, "result": "WA", "execution_time": "1714 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    m = n+1\n    # Write your code here:\n    for i in range(m//2):\n        qc.swap(i, m-i-1)\n    for i in range(m//2 - 1):\n        qc.swap(i+1, m-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 13, "result": "RE", "execution_time": "1483 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    m = n+1\n    # Write your code here:\n    for i in range((m+1)//2):\n        qc.swap(i, m-i-1)\n    for i in range((m+1)//2 - 1):\n        qc.swap(i+1, m-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 14, "result": "RE", "execution_time": "1521 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    m = n+1\n    # Write your code here:\n    for i in range(m//2):\n        qc.swap(i, m-i-1)\n    for i in range((m+1)//2):\n        qc.swap(i+1, m-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8A84F97E6280", "submission_order": 15, "result": "AC", "execution_time": "1971 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    m = n+1\n    # Write your code here:\n    for i in range(m//2):\n        qc.swap(i, m-i-1)\n    if m%2==1:\n        for i in range(m//2):\n            qc.swap(i+1, m-i-1)\n    else:\n        for i in range(m//2 - 1):\n            qc.swap(i+1, m-i-1)\n\n\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8BE21D9C1852", "submission_order": 1, "result": "WA", "execution_time": "1623 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(4):\n        for j in range(0, n - 2**i, 2 * 2**i):\n            qc.swap(j,j+2**i)\n            \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A8BE21D9C1852", "submission_order": 2, "result": "RE", "execution_time": "1273 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    n=n+1\n    qc = QuantumCircuit(n)\n    for i in range(4):\n        for j in range(0, n - 2**i, 2 * 2**i):\n            qc.swap(j,j+2**i)\n            \n    return qc\ns\n'''"}
{"problem": "QPC005_A4", "user": "A8BE21D9C1852", "submission_order": 3, "result": "AC", "execution_time": "2204 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    n+=1\n    for i in range(4):\n        for j in range(0, n - 2**i, 2 * 2**i):\n            qc.swap(j,j+2**i)\n            \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A94EE3EDB688D", "submission_order": 1, "result": "WA", "execution_time": "1487 ms", "memory": "142 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    def gao(l, r):\n        if r - l == 1:\n            return\n        m = (l + r) // 2\n        qc.swap(l, m)\n        gao(l, m)\n        gao(m, r)\n\n    gao(0, n + 1)\n    return qc\n\n# p = [i for i in range(9)]\n# def gao(l, r):\n#     if r - l == 1:\n#         return\n#     m = (l + r) // 2\n#     p[l], p[m] = p[m], p[l]\n#     gao(l, m)\n#     gao(m, r)\n# gao(0, len(p))\n# print(p)\n# exit(0)\n'''"}
{"problem": "QPC005_A4", "user": "A94EE3EDB688D", "submission_order": 2, "result": "AC", "execution_time": "1978 ms", "memory": "143 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    def gao(l, r):\n        if r - l == 1:\n            return\n        m = (l + r) // 2\n        qc.swap(l, m)\n        gao(l, m)\n        gao(m, r)\n\n    gao(0, n + 1)\n    return qc.inverse()\n\n# p = [i for i in range(9)]\n# def gao(l, r):\n#     if r - l == 1:\n#         return\n#     m = (l + r) // 2\n#     p[l], p[m] = p[m], p[l]\n#     gao(l, m)\n#     gao(m, r)\n# gao(0, len(p))\n# print(p)\n# exit(0)\n'''"}
{"problem": "QPC005_A4", "user": "A9859A12ED3DF", "submission_order": 1, "result": "DLE", "execution_time": "1450 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range((n + 1)//2):\n        qc.cx(i, n - i)\n        qc.cx(n - i, i)\n        qc.cx(i, n - i)\n    for i in range(1, (n + 1)//2 + (n + 1)%2):\n        qc.cx(i, n + 1 - i)\n        qc.cx(n + 1 - i, i)\n        qc.cx(i, n + 1 - i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 1, "result": "DLE", "execution_time": "1329 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range(0, n):\n        qc.cx(n, i)\n    for i in range(0, n):\n        qc.cx(i, n)\n    for i in range(0, n):\n        qc.cx(n, i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 2, "result": "WA", "execution_time": "1857 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range((n + 1) // 2):\n        qc.swap(2 * i, 2 * i + 1)\n    for i in range((n + 1)// 4):\n        qc.swap(4 * i, 4 * i + 2)\n    if (n == 10):\n        qc.swap(8, 10)\n    for i in range((n + 1) // 8):\n        qc.swap(8 * i, 8 * i + 4)\n    \n    if (n >= 8):\n        qc.swap(0, 8)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 3, "result": "WA", "execution_time": "1778 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range((n + 1) // 2):\n        qc.swap(2 * i, 2 * i + 1)\n    for i in range((n + 1) // 4):\n        qc.swap(4 * i, 4 * i + 2)\n    #if (n == 10):\n        #qc.swap(8, 10)\n    for i in range((n + 1) // 8):\n        qc.swap(8 * i, 8 * i + 4)\n    \n    if (n >= 8):\n        qc.swap(0, 8)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 4, "result": "RE", "execution_time": "1812 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    i = 0\n    while(2 * i + 1 >= n):\n        qc.swap(2 * i, 2 * i + 1)\n    i = 0\n    while(4 * i + 2 >= n):\n        qc.swap(4 * i, 4 * i + 2)\n    while(8 * i + 4 >= n):\n        qc.swap(8 * i, 8 * i + 4)\n    \n    if (n >= 8):\n        qc.swap(0, 8)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 5, "result": "TLE", "execution_time": "3000 ms", "memory": "149 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    i = 0\n    while(2 * i + 1 < n):\n        qc.swap(2 * i, 2 * i + 1)\n    i = 0\n    while(4 * i + 2 < n):\n        qc.swap(4 * i, 4 * i + 2)\n    while(8 * i + 4 < n):\n        qc.swap(8 * i, 8 * i + 4)\n    \n    if (n >= 8):\n        qc.swap(0, 8)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    i = 0\n    while(2 * i + 1 < n):\n        qc.swap(2 * i, 2 * i + 1)\n        i++\n    i = 0\n    while(4 * i + 2 < n):\n        qc.swap(4 * i, 4 * i + 2)\n        i++\n    while(8 * i + 4 < n):\n        qc.swap(8 * i, 8 * i + 4)\n        i++\n    if (n >= 8):\n        qc.swap(0, 8)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 7, "result": "WA", "execution_time": "1633 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    i = 0\n    while(2 * i + 1 < n):\n        qc.swap(2 * i, 2 * i + 1)\n        i += 1\n    i = 0\n    while(4 * i + 2 < n):\n        qc.swap(4 * i, 4 * i + 2)\n        i += 1\n    i = 0\n    while(8 * i + 4 < n):\n        qc.swap(8 * i, 8 * i + 4)\n        i += 1\n    if (n >= 8):\n        qc.swap(0, 8)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 8, "result": "WA", "execution_time": "1744 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    i = 0\n    while(2 * i + 1 < n):\n        qc.swap(2 * i, 2 * i + 1)\n        i += 1\n    i = 0\n    while(4 * i + 2 < n):\n        qc.swap(4 * i, 4 * i + 2)\n        i += 1\n    i = 0\n    while(8 * i + 4 < n):\n        qc.swap(8 * i, 8 * i + 4)\n        i += 1\n    if (n % 2 == 0):\n        qc.swap(0, n)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 9, "result": "WA", "execution_time": "1656 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    i = 0\n    while(2 * i + 1 <= n):\n        qc.swap(2 * i, 2 * i + 1)\n        i += 1\n    i = 0\n    while(4 * i + 2 <= n):\n        qc.swap(4 * i, 4 * i + 2)\n        i += 1\n    i = 0\n    while(8 * i + 4 <= n):\n        qc.swap(8 * i, 8 * i + 4)\n        i += 1\n    if (n % 2 == 0):\n        qc.swap(0, n)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 10, "result": "WA", "execution_time": "2010 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    i = 0\n    while(2 * i + 1 <= n):\n        qc.swap(2 * i, 2 * i + 1)\n        i += 1\n    i = 0\n    while(4 * i + 2 <= n):\n        qc.swap(4 * i, 4 * i + 2)\n        i += 1\n    i = 0\n    while(8 * i + 4 <= n):\n        qc.swap(8 * i, 8 * i + 4)\n        i += 1\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "A9C7568F756AB", "submission_order": 11, "result": "AC", "execution_time": "1929 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    i = 0\n    while(2 * i + 1 <= n):\n        qc.swap(2 * i, 2 * i + 1)\n        i += 1\n    i = 0\n    while(4 * i + 2 <= n):\n        qc.swap(4 * i, 4 * i + 2)\n        i += 1\n    i = 0\n    while(8 * i + 4 <= n):\n        qc.swap(8 * i, 8 * i + 4)\n        i += 1\n    i = 0\n    while(16 * i + 8 <= n):\n        qc.swap(16 * i, 16 * i + 8)\n        i += 1\n    i = 0\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AA91DA458E285", "submission_order": 1, "result": "RE", "execution_time": "1558 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range((n + 1).bit_length()):\n        for j in range(0, n + 1 - 2 ** (i - 1), 2 ** i):\n            qc.swap(j, j + 2 ** i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AA91DA458E285", "submission_order": 2, "result": "RE", "execution_time": "1637 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range((n + 1).bit_length()):\n        for j in range(0, n + 1 - 2 ** (i - 1), 2 ** i):\n            qc.swap(j, j + 2 ** i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AA91DA458E285", "submission_order": 3, "result": "AC", "execution_time": "2446 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in range((n + 1).bit_length()):\n        for j in range(0, n + 1 - 2 ** i, 2 ** (i + 1)):\n            qc.swap(j, j + 2 ** i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AB25681CB768D", "submission_order": 1, "result": "AC", "execution_time": "1915 ms", "memory": "143 MiB", "code": "'''python\nfrom math import pi\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import HGate\n\ndef sw(qc: QuantumCircuit, arr):\n    narr = []\n    if len(arr) % 2 == 0:\n        for i in range(0, len(arr), 2):\n            qc.swap(arr[i], arr[i + 1])\n            narr.append(arr[i])\n    else:\n        narr.append(arr[0])\n        for i in range(1, len(arr), 2):\n            qc.swap(arr[i], arr[i + 1])\n            narr.append(arr[i])\n    return narr\n\n\ndef solve(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(n + 1)\n    \n    arr = list(range(n + 1))\n    while len(arr) > 1:\n        arr = sw(qc, arr)\n        print(arr)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AB2F40010B8F9", "submission_order": 1, "result": "WA", "execution_time": "1667 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    # qc.x(0)\n    \n    for i in range(n):\n        qc.swap(i,i+1)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A4", "user": "AB2F40010B8F9", "submission_order": 2, "result": "DLE", "execution_time": "1546 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    # qc.x(0)\n    \n    for i in reversed(range(n)):\n        qc.swap(i,i+1)\n \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A4", "user": "AB2F40010B8F9", "submission_order": 3, "result": "WA", "execution_time": "1748 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    # qc.x(0)\n    \n    qc.cx(0,1)\n    for i in range(n-1):\n        qc.cx(i+1,i)\n        if i+2<n:\n            qc.cx(i,i+2)\n        else:\n            qc.cx(i,i+1)\n \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A4", "user": "AB2F40010B8F9", "submission_order": 4, "result": "AC", "execution_time": "1735 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    # qc.x(1)\n    \n    d=1\n    while d<=n+1:\n        for i in range(0,n,d*2):\n            if i+d<n+1:\n                print(i,i+d)\n                qc.swap(i,i+d)\n        d<<=1\n    \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A4", "user": "AB5C0146D7BF6", "submission_order": 1, "result": "WA", "execution_time": "1819 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    for i in reversed(range(n)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "ABE66CC60232E", "submission_order": 1, "result": "WA", "execution_time": "1990 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    stride = 2\n    while stride < n + 1:\n        for i in range(0, n + 1, stride):\n            if i + stride // 2 < n + 1:\n                qc.swap(i, i + stride // 2)\n        stride *= 2\n\n    if (n + 1) % 2 == 1:\n        qc.swap(0, n)\n\n    return qc\n\n\ndef main():\n    print(solve(1))\n    print(solve(2))\n    print(solve(7))\n    print(solve(8))\n    print(solve(9))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A4", "user": "ABE66CC60232E", "submission_order": 2, "result": "WA", "execution_time": "1697 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    stride = 2\n    while stride < n + 1:\n        for i in range(0, n + 1, stride):\n            if i + stride // 2 < n + 1:\n                qc.swap(i, i + stride // 2)\n        stride *= 2\n\n    qc.swap(0, n)\n\n    return qc\n\n\ndef main():\n    print(solve(1))\n    print(solve(2))\n    print(solve(7))\n    print(solve(8))\n    print(solve(9))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A4", "user": "ABE66CC60232E", "submission_order": 3, "result": "AC", "execution_time": "1987 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    stride = 1\n    while stride < n + 1:\n        for i in range(0, n + 1, stride * 2):\n            if i + stride < n + 1:\n                qc.swap(i, i + stride)\n        stride *= 2\n\n    # qc.swap(0, n)\n\n    return qc\n\n\ndef main():\n    for n in range(1, 11):\n        print(n)\n        print(solve(n))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A4", "user": "AC3267EF9864D", "submission_order": 1, "result": "AC", "execution_time": "1835 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    blk = 1\n    while blk <= n:\n        for i in range(0, n + 1, blk * 2):\n            if i + blk <= n:\n                qc.swap(i, i + blk)\n        blk *= 2\n \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AD8FDD72C9535", "submission_order": 1, "result": "DLE", "execution_time": "1412 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n\n    for i in range(n):\n        qc.cx(n, i)\n    \n    for i in range(n):\n        qc.cx(i, n)\n    \n    for i in range(n):\n        qc.cx(n, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AD8FDD72C9535", "submission_order": 2, "result": "DLE", "execution_time": "1506 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n\n    for i in range(n, 0, -1):\n        qc.swap(i, i-1)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AD8FDD72C9535", "submission_order": 3, "result": "RE", "execution_time": "1441 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n\n    for i in reversed(range(n + 1)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AD8FDD72C9535", "submission_order": 4, "result": "WA", "execution_time": "2119 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n\n    for i in reversed(range(n)):\n        qc.cx(i, i + 1)\n        qc.cx(i + 1, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AD8FDD72C9535", "submission_order": 5, "result": "DLE", "execution_time": "1354 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n\n    for i in range(n):\n        qc.swap(n - i, n - i - 1)\n    \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AE59CD727BE49", "submission_order": 1, "result": "WA", "execution_time": "1573 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    num_swaps = (n+1) // 2\n    for i in range(num_swaps):\n        qc.swap(i, n - i)\n        \n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AE59CD727BE49", "submission_order": 2, "result": "WA", "execution_time": "1834 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    num_swaps = (n+1) // 2\n    for i in range(num_swaps):\n        qc.cx(i, n - i)\n        qc.cx(n - i, i)\n        qc.cx(i, n - i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AE59CD727BE49", "submission_order": 3, "result": "WA", "execution_time": "1983 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    for i in reversed(range(n)):\n        qc.cx(i, i+1)\n        qc.cx(i+1, i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AE59CD727BE49", "submission_order": 4, "result": "WA", "execution_time": "1709 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    num_swaps = (n+1) // 2\n    for i in range(num_swaps):\n        qc.swap(i, n-i)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AE59CD727BE49", "submission_order": 5, "result": "WA", "execution_time": "1695 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    qc.swap(0, n)\n    return qc\n'''"}
{"problem": "QPC005_A4", "user": "AE59CD727BE49", "submission_order": 6, "result": "RE", "execution_time": "1525 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    for i in range(n):\n        qc.swap(n-i, n+1-i)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A01641124A53E", "submission_order": 1, "result": "AC", "execution_time": "1830 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    # twos complement, flip all, plus one\n    for i in range(n):\n        qc.x(i)\n\n    # from 004 - A5 editorial\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A157E717D2F7D", "submission_order": 1, "result": "AC", "execution_time": "1886 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1,n):\n        qc.mcx(list(range(i)),i)\n    qc.x(range(n))\n \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A221208DDB1AF", "submission_order": 1, "result": "AC", "execution_time": "2419 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.x(i)\n    \n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A3483E2DB4DF6", "submission_order": 1, "result": "AC", "execution_time": "1816 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A47F627D27D94", "submission_order": 1, "result": "RE", "execution_time": "1619 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n-1, 0, -1):\n        mx = XGate().control(i)\n        qubit = list(range(i+1))\n        # print(i, qubit)\n        qc.append(mx, qubit)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A47F627D27D94", "submission_order": 2, "result": "AC", "execution_time": "2223 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n-1, 0, -1):\n        mx = XGate().control(i)\n        qubit = list(range(i+1))\n        # print(i, qubit)\n        qc.append(mx, qubit)\n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A4B28D25BA17A", "submission_order": 1, "result": "WA", "execution_time": "1460 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A4B28D25BA17A", "submission_order": 2, "result": "AC", "execution_time": "1887 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A5B55B1C78595", "submission_order": 1, "result": "WA", "execution_time": "1626 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A5B55B1C78595", "submission_order": 2, "result": "WA", "execution_time": "1524 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in range(n-1,0,-1):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n\n    for i in range(n):\n        qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A5B55B1C78595", "submission_order": 3, "result": "AC", "execution_time": "1811 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.x(i)\n\n \n    for i in range(n-1,0,-1):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n\n\n \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A5C08BCA491D7", "submission_order": 1, "result": "AC", "execution_time": "1935 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.x(i)\n    \n    # increment\n    for i in reversed(range(n)):\n        if i:\n            qc.append(XGate().control(i), list(range(i + 1)))\n        else:\n            qc.x(i)\n \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A6433F0BFCA9A", "submission_order": 1, "result": "AC", "execution_time": "1894 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    \n    # qc.x(0)\n\n    for i in range(n):\n        qc.x(i)\n\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_A5", "user": "A6BD0859C6799", "submission_order": 1, "result": "RE", "execution_time": "1624 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n    for i in range(n):\n        for j in range(i):\n            qc.cp(pi / 2 ** (i - j), j, i)  # 角度の符号を反転\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A6BD0859C6799", "submission_order": 2, "result": "DLE", "execution_time": "2077 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n    for i in range(n):\n        for j in range(i):\n            qc.cp(pi / 2 ** (i - j), j, i)  # 角度の符号を反転\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A6E12E975E9B2", "submission_order": 1, "result": "RE", "execution_time": "1441 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / (2**(i - j)), j, i)\n\n    for i in range(n):\n        qc.p(2 * np.pi / (2**(n - i)), i)\n\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-np.pi / (2**(i - j)), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A6E12E975E9B2", "submission_order": 2, "result": "WA", "execution_time": "1566 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n - 1, -1, -1):\n        qc.h(i)\n        for j in range(i - 1, -1, -1):\n            qc.cp(np.pi / (2**(i - j)), j, i)\n\n    for i in range(n):\n        qc.p(2 * np.pi / (2**(n - i)), i)\n\n    for i in range(n):\n        for j in range(i):\n            qc.cp(-np.pi / (2**(i - j)), j, i)\n        qc.h(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A6E12E975E9B2", "submission_order": 3, "result": "UGE", "execution_time": "1521 ms", "memory": "140 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\n\n\ndef add1(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n\n    qc.x(0)\n\n    return qc\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        qc.x(i)\n    qc.append(add1(n), range(n))\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A6E12E975E9B2", "submission_order": 4, "result": "AC", "execution_time": "1805 ms", "memory": "143 MiB", "code": "'''python\nimport numpy as np\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    qc.x(range(n))\n\n    for i in reversed(range(1, n)):\n        num_controls = i\n        mcx_gate = XGate().control(num_controls)\n        qubits_to_apply = list(range(i + 1))\n        qc.append(mcx_gate, qubits_to_apply)\n    \n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A713B2C17B5B9", "submission_order": 1, "result": "DLE", "execution_time": "1579 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef qft(n: int) -> QuantumCircuit:\n    x = QuantumRegister(n)\n    qc = QuantumCircuit(x)\n\n    for i in range(n):\n        qc.h(x[-(i + 1)])\n\n        for j in range(i + 1, n):\n            qc.cp(np.pi / (2 ** (j - i)), x[-(j + 1)], x[-(i + 1)])\n\n    for i in range(n // 2):\n        qc.swap(x[i], x[-(i + 1)])\n\n    return qc\n\n\ndef solve(n) -> QuantumCircuit:\n\n    qc = QuantumCircuit(n)\n    qc.compose(qft(n), inplace=True)\n    qc.compose(qft(n), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A713B2C17B5B9", "submission_order": 2, "result": "AC", "execution_time": "1804 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef solve(n) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(range(n))\n\n    for idx in reversed(range(n)):\n        if idx == 0:\n            qc.x(idx)\n        else:\n            qc.mcx(list(range(idx)), idx)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 1, "result": "WA", "execution_time": "1595 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n    # インクリメント（Ripple carry加算器の最小構成）\n    for i in range(n):\n        qc.x(i)\n        if i == 0:\n            break\n        for j in reversed(range(1, i+1)):\n            qc.ccx(j-1, j, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 2, "result": "WA", "execution_time": "1749 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n):\n        qc.x(i)\n        for j in range(i):\n            qc.cx(j, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 3, "result": "WA", "execution_time": "1667 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    for i in reversed(range(n)):\n        qc.x(i)\n        for j in reversed(range(i)):\n            qc.cx(j, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    def solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    for i in range(n):\n        qc.x(i)\n    # +1のインクリメント（nビットRipple Carry）\n    for i in range(n):\n        # 1桁目はXだけ\n        if i == 0:\n            qc.x(0)\n        else:\n            # それ以降は、下位がすべて1のとき反転 (全て1かどうかの多重制御X)\n            controls = [j for j in range(i)]\n            qc.mcx(controls, i)\n\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 5, "result": "WA", "execution_time": "1660 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    for i in range(n):\n        qc.x(i)\n    # +1のインクリメント（nビットRipple Carry）\n    for i in range(n):\n        # 1桁目はXだけ\n        if i == 0:\n            qc.x(0)\n        else:\n            # それ以降は、下位がすべて1のとき反転 (全て1かどうかの多重制御X)\n            controls = [j for j in range(i)]\n            qc.mcx(controls, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 6, "result": "WA", "execution_time": "1508 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    for i in range(n):\n        # i=0: 最下位ビットは必ず反転\n        if i == 0:\n            qc.x(0)\n        else:\n            # それまでのビットが全て1なら反転\n            qc.mcx(list(range(i)), i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 7, "result": "WA", "execution_time": "1495 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n+1)\n    # (1) すべてのビットを反転（Xゲート）\n    for i in range(n):\n        qc.x(i)\n    # (2) +1 のインクリメント（LSBからMSBへのキャリー伝播）\n    for i in range(n):\n        if i == 0:\n            qc.x(0)\n        else:\n            qc.mcx(list(range(i)), i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 8, "result": "WA", "execution_time": "1660 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # (1) すべてのビットを反転（Xゲート）\n    for i in range(n):\n        qc.x(i)\n    # (2) +1 のインクリメント（LSBからMSBへのキャリー伝播）\n    for i in range(n):\n        if i == 0:\n            qc.x(0)\n        else:\n            qc.mcx(list(range(i)), i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 9, "result": "WA", "execution_time": "1541 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # すべてのビットを反転\n    for i in range(n):\n        qc.x(i)\n    # +1（インクリメント）\n    for i in range(n):\n        if i == 0:\n            qc.x(0)\n        else:\n            qc.mcx(list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A7683C9C7BDCA", "submission_order": 10, "result": "WA", "execution_time": "1483 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # (1) 全ビット反転\n    for i in range(n):\n        qc.x(i)\n    # (2) +1加算\n    # ここは「位ごとの多重制御X（キャリー）」でリトルエンディアン\n    for i in range(n):\n        if i == 0:\n            qc.x(0)\n        else:\n            qc.mcx(list(range(i)), i)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A768B79BDAC10", "submission_order": 1, "result": "WA", "execution_time": "1778 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n):\n        if i == 0:\n            qc.x(i)\n        else:\n            # Create carry chain\n            controls = list(range(i))\n            qc.mcx(controls, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A768B79BDAC10", "submission_order": 2, "result": "WA", "execution_time": "1531 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n   \n    for i in range(n):\n        qc.x(i)\n\n    for i in range(n):\n        if i == 0:\n            qc.x(0)\n        else:\n            qc.mcx(list(range(i)), i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A768B79BDAC10", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n    qc.x(0)\n    \n    for i in range(n):\n        qc.x(i\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A768B79BDAC10", "submission_order": 4, "result": "WA", "execution_time": "1705 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n    qc.x(0)\n    \n    for i in range(n):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A768B79BDAC10", "submission_order": 5, "result": "RE", "execution_time": "1393 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        controls = list(range(i))\n        qc.mcx(controls, i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A768B79BDAC10", "submission_order": 6, "result": "RE", "execution_time": "1411 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.x(i)\n    for i in range(n):\n        controls = list(range(i))\n        qc.mcx(controls, i)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A8C14513E246D", "submission_order": 1, "result": "WA", "execution_time": "1703 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(1, n):\n        for j in range(i):\n            qc.x(j)\n        qc.mcx(list(range(i)), i)\n        for j in range(i):\n            qc.x(j)\n    \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A8C14513E246D", "submission_order": 2, "result": "WA", "execution_time": "1575 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n-1, 0, -1):\n        for j in range(i):\n            qc.cx(j, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A8C14513E246D", "submission_order": 3, "result": "RE", "execution_time": "1422 ms", "memory": "141 MiB", "code": "'''python\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(0,n):\n        qc.cx(i+1,i)\n    \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A8C14513E246D", "submission_order": 4, "result": "AC", "execution_time": "1772 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    qc.x(range(n))\n    \n    for i in range(n - 1, 0, -1):\n        control_qubits = list(range(i))\n        qc.mcx(control_qubits, qc.qubits[i])\n        \n    qc.x(0)\n    \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A8C95B4D92747", "submission_order": 1, "result": "WA", "execution_time": "1608 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n \n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A8C95B4D92747", "submission_order": 2, "result": "WA", "execution_time": "1543 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    \n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n \n    \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A8C95B4D92747", "submission_order": 3, "result": "WA", "execution_time": "1530 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    # -x = (x+1) mod n\n    qc.x(0)\n    \n    for i in range(n):\n        if i == 0:\n            qc.x(0)  # flip bit thấp nhất luôn luôn\n        else:\n            qc.mcx(list(range(i)), i)\n \n    \n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A923C5AEC8CC7", "submission_order": 1, "result": "AC", "execution_time": "1931 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \ndef add1(qc: QuantumCircuit, n: int) -> QuantumCircuit:\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)), i)\n    qc.x(0)\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    qc.x(range(n))\n    add1(qc, n)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "A92D79E74FF97", "submission_order": 1, "result": "AC", "execution_time": "2106 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    for i in reversed(range(1, n)):\n        qc.mcx(list(range(i)),i)\n    qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "AACA18EC9B5FC", "submission_order": 1, "result": "AC", "execution_time": "1924 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(range(n))\n    for i in range(n-1, 0, -1):\n        qc.mcx(list(range(i)), i)\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "AC1282A0C43D1", "submission_order": 1, "result": "AC", "execution_time": "1952 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n\n    qc = QuantumCircuit(n)\n\n    for q in range(n):\n        qc.x(q)\n\n    for i in range(n - 1, 0, -1):          \n        controls = list(range(i))           \n        qc.mcx(controls, i)                 \n\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "AC2AFD400934C", "submission_order": 1, "result": "RE", "execution_time": "1335 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(1, n - 1):\n        qc.x(i)\n\n    for i in range(1, n - 1):\n        qc.cnot(i - 1, i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "AC70CAAC7675B", "submission_order": 1, "result": "AC", "execution_time": "1750 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.x(i)\n\n    for l in range(n - 1, 0, -1):\n        qc.mcx(list(range(l)), l)\n    qc.x(0)\n\n    return qc\n\n\ndef main():\n    print(solve(1))\n    print(solve(2))\n    print(solve(3))\n    print(solve(4))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_A5", "user": "ACE7BE3BBD0AE", "submission_order": 1, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(i, n))\n\n    for i in range(n-1):\n        qc.x(i)\n        qc.append(XGate(i), in range(i-1))\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "ACE7BE3BBD0AE", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(i, n))\n\n\n    for i in range(n-1):\n        qc.x(i)\n        qc.append(XGate().control(i - 1), in range(i))\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "ACE7BE3BBD0AE", "submission_order": 3, "result": "RE", "execution_time": "2022 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(i, n))\n\n\n    for i in range(n-1):\n        qc.x(i)\n        qc.append(XGate().control(i - 1), range(i))\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "ACE7BE3BBD0AE", "submission_order": 4, "result": "RE", "execution_time": "1493 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(1, n))\n\n    for i in range(n-1):\n        #qc.barrier()\n        qc.x(i)\n        qc.append(XGate().control(i+1), range(i + 2))\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "ACE7BE3BBD0AE", "submission_order": 5, "result": "WA", "execution_time": "1899 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if(n == 1):\n        return qc\n        \n    qc.x(range(1, n))\n\n    for i in range(n-1):\n        #qc.barrier()\n        qc.x(i)\n        qc.append(XGate().control(i+1), range(i + 2))\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "ACE7BE3BBD0AE", "submission_order": 6, "result": "AC", "execution_time": "2055 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    if(n == 1):\n        return qc\n        \n    qc.x(range(1, n))\n\n    for i in range(n-1):\n        #qc.barrier()\n        qc.x(range(i + 1))\n        qc.append(XGate().control(i + 1), range(i + 2))\n        qc.x(range(i + 1))\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "AD196A32DFBDA", "submission_order": 1, "result": "WA", "execution_time": "1621 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(i for i in range(n))\n    for i in range(n-1):\n        qc.cx(i,i+1)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "AD196A32DFBDA", "submission_order": 2, "result": "RE", "execution_time": "1782 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(i for i in range(1,n))\n    for i in range(n-1):\n        qc.x(i)\n        qc.cx(i,i+1)\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "AD196A32DFBDA", "submission_order": 3, "result": "AC", "execution_time": "1918 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(i for i in range(n))\n    for i in reversed(range(1, n)):\n        qc.append(XGate().control(i), range(i + 1))\n    qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "ADEADBB0E772A", "submission_order": 1, "result": "AC", "execution_time": "2224 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\n \ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    qc.x(range(n))\n\n    for i in reversed(range(n)):\n        if i == 0:\n            qc.x(i)\n        else:\n            qc.append(XGate().control(i), range(i + 1))\n\n    return qc\n'''"}
{"problem": "QPC005_A5", "user": "AE81688D3508C", "submission_order": 1, "result": "AC", "execution_time": "1832 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.x(0)\n    for i in range(1, n):\n        qc.mcx(list(range(i)), i)\n    for i in range(n):\n        qc.x(i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A02710C95626C", "submission_order": 1, "result": "AC", "execution_time": "2001 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.append(PhaseGate(2 * pi / (1 << n) * k_const), [i])\n        k_const *= 2\n        k_const %= (1 << n)\n    \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A07A604976ACC", "submission_order": 1, "result": "WA", "execution_time": "1631 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * k_const / 2 ** n\n        qc.p(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A07A604976ACC", "submission_order": 2, "result": "AC", "execution_time": "1931 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * k_const * (2 ** i) / (2 ** n)\n        qc.p(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A14187ECAE8AD", "submission_order": 1, "result": "RE", "execution_time": "1873 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    w = np.pi / (2**n)\n\n    for i in range(n):\n        qc.p(w * (k_const - 1) ** (2**i), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A14187ECAE8AD", "submission_order": 2, "result": "WA", "execution_time": "1733 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    w = np.pi / (2**n)\n\n    for i in range(n):\n        qc.p(w * (k_const - 1) * (2**i), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A14187ECAE8AD", "submission_order": 3, "result": "WA", "execution_time": "1757 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    w = 2 * np.pi / (2**n)\n\n    for i in range(n):\n        qc.p(w * (k_const - 1) * (2**i), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A14187ECAE8AD", "submission_order": 4, "result": "WA", "execution_time": "1616 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    w = np.exp(1j * np.pi / (2**n))\n\n    for i in range(n):\n        qc.p(np.angle(w ** ((k_const - 1) * (2**i))), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A14187ECAE8AD", "submission_order": 5, "result": "WA", "execution_time": "1579 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    w = np.exp(1j * np.pi / (2**n))\n\n    for i in range(n):\n        qc.p(np.angle(w ** (k_const * (2**i))), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A14187ECAE8AD", "submission_order": 6, "result": "AC", "execution_time": "1678 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    w = np.exp(2j * np.pi / (2**n))\n\n    for i in range(n):\n        qc.p(np.angle(w ** (k_const * (2**i))), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A206E331453E5", "submission_order": 1, "result": "WA", "execution_time": "1426 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (k_const >> i) % 2 == 1:\n            qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A206E331453E5", "submission_order": 2, "result": "WA", "execution_time": "1484 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if (k_const >> i) % 2 == 1:\n            qc.x(n-1-i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A206E331453E5", "submission_order": 3, "result": "RE", "execution_time": "1778 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    wconst = 2 * math.pi * k_const / (2 ** n)\n\n    for i in range(n):\n        theta = wconst ** (1 << i)\n        qc.p(theta, i)\n        \n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A206E331453E5", "submission_order": 4, "result": "AC", "execution_time": "1988 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    wconst = 2 * math.pi * k_const / (2 ** n)\n\n    for i in range(n):\n        theta = wconst * (1 << i)\n        qc.p(theta, i)\n        \n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A2B6882E792B5", "submission_order": 1, "result": "WA", "execution_time": "1813 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    I=[]\n    for i in range(n):\n        I.append(k_const%2)\n        k_const//=2\n    for i in range(n):\n        if I[i]:\n            qc.x(i)\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A2B6882E792B5", "submission_order": 2, "result": "RE", "execution_time": "1613 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    I=[]\n    for i in range(n):\n        I.append(k_const%2)\n        k_const//=2\n    for i in range(n):\n        if I[i]:\n            theta = 2*math.pi/2**n\n            qc.p(theta, i)\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A2B6882E792B5", "submission_order": 3, "result": "WA", "execution_time": "1509 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    I=[]\n    for i in range(n):\n        I.append(k_const%2)\n        k_const//=2\n    for i in range(n):\n        if I[i]:\n            theta = 2*math.pi/2**n\n            qc.p(theta, i)\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A2B6882E792B5", "submission_order": 4, "result": "AC", "execution_time": "1709 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for i in range(n):\n        theta = k_const*2*math.pi/2**n\n        qc.p(theta*(2**i), i)\n    # Write your code here:\n \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A55AAF8BEE4E7", "submission_order": 1, "result": "RE", "execution_time": "1571 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.z(k_const, range(n))\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A55AAF8BEE4E7", "submission_order": 2, "result": "WA", "execution_time": "1625 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.rz(k_const, range(n))\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A55AAF8BEE4E7", "submission_order": 3, "result": "WA", "execution_time": "1524 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rz(i * k_const, i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A55AAF8BEE4E7", "submission_order": 4, "result": "WA", "execution_time": "1666 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rz(2 * i * k_const * np.pi / np.power(2, n), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A55AAF8BEE4E7", "submission_order": 5, "result": "WA", "execution_time": "1689 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rz(2 * i * k_const * np.pi / (2**n), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A55AAF8BEE4E7", "submission_order": 6, "result": "AC", "execution_time": "1679 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.rz(2 * (2 ** i) * k_const * np.pi / (2 ** n), i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A5B3DDABDCDE0", "submission_order": 1, "result": "AC", "execution_time": "2023 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for s in range(n):\n        qc.p(pi*2 * 2**(s-n) * k_const, s)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A5EBCD9E10BAD", "submission_order": 1, "result": "AC", "execution_time": "2001 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \n \ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n \n    for i in range(n):\n        angle = 2 * math.pi / (2**n) * k_const * (2**i)\n        qc.p(angle, i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A6A6CD8961C46", "submission_order": 1, "result": "AC", "execution_time": "1944 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for j in range(n):\n        lambda_j = (2 * np.pi * k_const) / (2**(n - j))\n        \n        if lambda_j != 0:\n            qc.p(lambda_j, j)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A81824D7C291F", "submission_order": 1, "result": "RE", "execution_time": "1481 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    omega_angle = 2 * np.pi * k_const / (2**n)\n    for j in range(n):\n        angle = (2 ** j) * omega_angle  \n        qc.rz(angle, j)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A81824D7C291F", "submission_order": 2, "result": "RE", "execution_time": "1417 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    omega_angle = 2 * np.pi * k_const / (2**n)\n    for j in range(n):\n        angle = (2 ** j) * omega_angle  \n        qc.p(angle, j)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A81824D7C291F", "submission_order": 3, "result": "RE", "execution_time": "1366 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    omega_angle = 2 * np.pi * k_const / (2**n)\n    for j in range(n):\n        angle = (2 ** j) * omega_angle  \n        qc.u1(angle, j)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A81824D7C291F", "submission_order": 4, "result": "RE", "execution_time": "1560 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    omega_angle = 2 * np.pi * k_const / (2**n)\n    for j in range(n):\n        angle = (2 ** j) * omega_angle  \n        qc.p(angle, j)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A81824D7C291F", "submission_order": 5, "result": "AC", "execution_time": "1680 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport numpy as np\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    omega_angle = 2 * np.pi * k_const / (2**n)\n    for j in range(n):\n        angle = (2 ** j) * omega_angle  \n        qc.p(angle, j)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A8EFE262A21E4", "submission_order": 1, "result": "RE", "execution_time": "1383 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    qc.h(n)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A90DD3397E700", "submission_order": 1, "result": "WA", "execution_time": "1943 ms", "memory": "142 MiB", "code": "'''python\nfrom math import pi\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2 * pi * k_const / 2**n, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A90DD3397E700", "submission_order": 2, "result": "RE", "execution_time": "1698 ms", "memory": "141 MiB", "code": "'''python\nfrom math import pi\nfrom qiskit import QuantumCircuit\n \n \ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        qc.p(2 * pi * int(bin(k_const)[:-1-i]) / 2**n, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A9288531CAC27", "submission_order": 1, "result": "WA", "execution_time": "1634 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    k_const_bits = []\n    temp = k_const\n    for i in range(n):\n        k_const_bits.append(temp % 2)\n        temp //= 2\n    \n    for j in range(n):\n        if k_const_bits[j] == 1:\n            angle = 2 * math.pi / (2**(n-j))\n            qc.p(angle, j)\n    \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A9288531CAC27", "submission_order": 2, "result": "WA", "execution_time": "1471 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for j in range(n):\n        angle = 0\n        for i in range(n):\n            if (k_const >> i) & 1:\n                if i <= j:\n                    angle += math.pi / (2**(j - i))\n        \n        if angle != 0:\n            qc.p(2 * angle, j)\n    \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A9288531CAC27", "submission_order": 3, "result": "WA", "execution_time": "1538 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n\n    for j in range(n):\n        phase_accumulator = 0.0\n        for i in range(n):\n            if (k_const >> i) & 1: \n                if i <= j:\n                    phase_accumulator += 1.0 / (2.0 ** (j - i + 1))\n        \n        if phase_accumulator > 0:\n            angle = 2.0 * math.pi * phase_accumulator\n            qc.p(angle, j)\n    \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A96CF8F6B691D", "submission_order": 1, "result": "RE", "execution_time": "1398 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi * k_const / (2 ** (i + 1))\n        qc.p(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A96CF8F6B691D", "submission_order": 2, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):￥\n        theta = 2 * math.pi * k_const / (2 ** (i + 1))\n        qc.p(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A96CF8F6B691D", "submission_order": 3, "result": "WA", "execution_time": "1573 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        theta = 2 * math.pi * k_const / (2 ** (i + 1))\n        qc.p(theta, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "A96CF8F6B691D", "submission_order": 4, "result": "AC", "execution_time": "1918 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    for i in range(n):\n        theta = 2 * math.pi * k_const / (2 ** (n - i))\n        qc.p(theta, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AAA65D3F49C59", "submission_order": 1, "result": "AC", "execution_time": "1837 ms", "memory": "142 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate\n \ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        theta = 2 * math.pi * k_const * 2 ** i / 2 ** n\n        qc.p(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AAB22FC1DD5B4", "submission_order": 1, "result": "RE", "execution_time": "1610 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2 ** (1 - n + i) * math.pi * k_const)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AAB22FC1DD5B4", "submission_order": 2, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2 ** (1 - n + i) * math.pi * k_const, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AAB22FC1DD5B4", "submission_order": 3, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport mat\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2 * math.pi / 2 ** n * 2 ** i * k_const, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AAB22FC1DD5B4", "submission_order": 4, "result": "AC", "execution_time": "2662 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2 ** (i + 1 - n) * math.pi * k_const, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AAF53979AB9B4", "submission_order": 1, "result": "AC", "execution_time": "1766 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import tau\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = tau * k_const * (1 << i) / (1 << n)\n        qc.p(theta, i)\n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AAF60924E35DA", "submission_order": 1, "result": "AC", "execution_time": "1976 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    \n    for i in range(n):\n        phase_angle = 2 * 3.141592653589793 * k_const / (2 ** (n - i))\n        qc.p(phase_angle, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AC6505D2B86B5", "submission_order": 1, "result": "AC", "execution_time": "1901 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        theta = 2 * math.pi / (2.0 ** (n - i)) * k_const\n        qc.p(theta, i)\n\n    return qc\n\n\ndef main():\n    print(solve(4, 1))\n    print(solve(4, 2))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_B1", "user": "AC761A94D17F0", "submission_order": 1, "result": "WA", "execution_time": "1603 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*k_const / 2**n, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AC761A94D17F0", "submission_order": 2, "result": "WA", "execution_time": "1593 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*k_const*(i+1) / 2**n, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AC761A94D17F0", "submission_order": 3, "result": "AC", "execution_time": "1800 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        qc.p(2*math.pi*k_const*2**(i) / 2**n, i)\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AE1735E36A60B", "submission_order": 1, "result": "AC", "execution_time": "1745 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n# from qiskit.quantum_info import Statevector\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n\n    for i in range(n):\n        rot=2*np.pi/2**n*k_const*(2**i)\n        # print(rot)\n        qc.p(rot,i)\n \n    return qc\n\n# if __name__ == \"__main__\":\n#     qc = solve(2,2)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B1", "user": "AF9AB4DB306F1", "submission_order": 1, "result": "AC", "execution_time": "1692 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    S = [k_const * (2 ** i) for i in range(n)]\n    for i in range(n):\n        theta = 2 * math.pi * S[i] / 2**n\n        qc.p(theta, i)    \n\n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AFCA95E240625", "submission_order": 1, "result": "WA", "execution_time": "1845 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        if k_const & (1<<i) :\n            phase_shift = 2 * pi * 2**i / (2 ** n)\n            qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AFCA95E240625", "submission_order": 2, "result": "WA", "execution_time": "1468 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        phase_shift = 2 * pi * 2**i / (2 ** n)\n        qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_B1", "user": "AFCA95E240625", "submission_order": 3, "result": "AC", "execution_time": "1852 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\n\ndef solve(n: int, k_const: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n    # Write your code here:\n    for i in range(n):\n        phase_shift = 2 * pi * 2**i * k_const / (2 ** n)\n        qc.p(phase_shift, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A09DFF99FF7F9", "submission_order": 1, "result": "UGE", "execution_time": "1417 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi / 2 ** (i - j), j, i)\n \n    # for i in range(n // 2):\n    #     qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    qc.append(qft(n),range(1,n+1))\n    \n    for j in range(n):\n        ang=2*np.pi*k_left/(2**(j+1))\n        qc.p(ang,j+1)\n        qc.cp(-2*ang,0,j+1)\n        \n    qc.append(qft(n).inverse(),range(1,n+1))\n    \n    if m_left:\n        qc.x(0)\n        \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(3,3,3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B2", "user": "A09DFF99FF7F9", "submission_order": 2, "result": "UGE", "execution_time": "1540 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi / 2 ** (i - j), j, i)\n \n    # for i in range(n // 2):\n    #     qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    qc.append(qft(n),range(1,n+1))\n    \n    # for j in range(n):\n    #     ang=2*np.pi*k_left/(2**(j+1))\n    #     qc.p(ang,j+1)\n    #     qc.cp(-2*ang,0,j+1)\n        \n    # qc.append(qft(n).inverse(),range(1,n+1))\n    \n    if m_left:\n        qc.x(0)\n        \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(3,3,3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B2", "user": "A09DFF99FF7F9", "submission_order": 3, "result": "UGE", "execution_time": "1475 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        # for j in reversed(range(i)):\n        #     qc.cp(np.pi / 2 ** (i - j), j, i)\n \n    # for i in range(n // 2):\n    #     qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    qc.append(qft(n),range(1,n+1))\n    \n    # for j in range(n):\n    #     ang=2*np.pi*k_left/(2**(j+1))\n    #     qc.p(ang,j+1)\n    #     qc.cp(-2*ang,0,j+1)\n        \n    # qc.append(qft(n).inverse(),range(1,n+1))\n    \n    if m_left:\n        qc.x(0)\n        \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(3,3,3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B2", "user": "A09DFF99FF7F9", "submission_order": 4, "result": "WA", "execution_time": "1623 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\n# def qft(n: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n \n#     for i in reversed(range(n)):\n#         qc.h(i)\n#         # for j in reversed(range(i)):\n#         #     qc.cp(np.pi / 2 ** (i - j), j, i)\n \n#     # for i in range(n // 2):\n#     #     qc.swap(i, n - i - 1)\n \n#     return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    # qc.append(qft(n),range(1,n+1))\n    \n    # for j in range(n):\n    #     ang=2*np.pi*k_left/(2**(j+1))\n    #     qc.p(ang,j+1)\n    #     qc.cp(-2*ang,0,j+1)\n        \n    # qc.append(qft(n).inverse(),range(1,n+1))\n    \n    if m_left:\n        qc.x(0)\n        \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(3,3,3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B2", "user": "A09DFF99FF7F9", "submission_order": 5, "result": "UGE", "execution_time": "1550 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    # for i in reversed(range(n)):\n    #     qc.h(i)\n        # for j in reversed(range(i)):\n        #     qc.cp(np.pi / 2 ** (i - j), j, i)\n \n    # for i in range(n // 2):\n    #     qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    qc.append(qft(n),range(1,n+1))\n    \n    # for j in range(n):\n    #     ang=2*np.pi*k_left/(2**(j+1))\n    #     qc.p(ang,j+1)\n    #     qc.cp(-2*ang,0,j+1)\n        \n    # qc.append(qft(n).inverse(),range(1,n+1))\n    \n    if m_left:\n        qc.x(0)\n        \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(3,3,3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B2", "user": "A09DFF99FF7F9", "submission_order": 6, "result": "WA", "execution_time": "1627 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi / 2 ** (i - j), j, i)\n \n    # for i in range(n // 2):\n    #     qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    qc.compose(qft(n),range(1,n+1),inplace=True)\n    \n    for j in range(n):\n        ang=2*np.pi*k_left/(2**(j+1))\n        qc.p(ang,j+1)\n        qc.cp(-2*ang,0,j+1)\n        \n    qc.compose(qft(n).inverse(),range(1,n+1),inplace=True)\n    \n    if m_left:\n        qc.x(0)\n        \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(3,3,3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B2", "user": "A09DFF99FF7F9", "submission_order": 7, "result": "WA", "execution_time": "1663 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    qc.compose(qft(n),range(1,n+1),inplace=True)\n    \n    for j in range(n):\n        ang=2*np.pi*k_left/(2**(j+1))\n        qc.p(ang,j+1)\n        qc.cp(-2*ang,0,j+1)\n        \n    qc.compose(qft(n).inverse(),range(1,n+1),inplace=True)\n    \n    if m_left:\n        qc.x(0)\n        \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(3,3,3)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B2", "user": "A09DFF99FF7F9", "submission_order": 8, "result": "WA", "execution_time": "1710 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import XGate\n\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(np.pi / 2 ** (i - j), j, i)\n \n    # for i in range(n // 2):\n    #     qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    \n    qc.compose(qft(n),range(1,n+1),inplace=True)\n    \n    for j in range(n):\n        ang=2*np.pi*k_left/(2**(j+1))\n        qc.p(ang,j+1)\n        qc.cp(-2*ang,0,j+1)\n        \n    qc.compose(qft(n).inverse(),range(1,n+1),inplace=True)\n    \n    if m_left:\n        qc.x(0)\n        \n    return qc\n\n# from qiskit.quantum_info import Statevector\n# if __name__ == \"__main__\":\n#     qc = solve(3,0,1)\n#     print(Statevector(qc))\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 1, "result": "RE", "execution_time": "1564 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.x(range(2,n+1))\n    qc.mcz(range(n),n)\n    qc.x(range(2,n+1))\n\n\n    if m_left%2 == 1: qc.x(0)\n    for i in range(k_left):\n        qc.rz(2 * pi * 2**(k_left*i - n + 1))\n\n    if m_left%2 == 1:\n        qc.x(range(2,n+1))\n        qc.mcx(range(2,n),0)\n        qc.x(range(2,n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 2, "result": "RE", "execution_time": "1546 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.x(range(2,n+1))\n    qc.mcz(range(n),n)\n    qc.x(range(2,n+1))\n\n\n    if m_left%2 == 1: qc.x(0)\n    for i in range(n-1):\n        qc.rz(2 * pi * 2**(k_left*i - n + 1), i+2)\n\n    if m_left%2 == 1:\n        qc.x(range(2,n+1))\n        qc.mcx(range(2,n),0)\n        qc.x(range(2,n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 3, "result": "RE", "execution_time": "1392 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.x(range(2,n+1))\n    qc.append(ZGate().control(n), range(n+1))\n    #qc.mcz(range(n),n)\n    qc.x(range(2,n+1))\n\n\n    if m_left%2 == 1: qc.x(0)\n    for i in range(n-1):\n        qc.rz(2 * pi * 2**(k_left*i - n + 1), i+2)\n\n    if m_left%2 == 1:\n        qc.x(range(2,n+1))\n        qc.mcx(list(range(2,n)),0)\n        qc.x(range(2,n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 4, "result": "RE", "execution_time": "1853 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.x(range(2,n+1))\n    qc.append(ZGate().control(n), range(n+1))\n    #qc.mcz(range(n),n)\n    qc.x(range(2,n+1))\n\n\n    if m_left%2 == 1: qc.x(0)\n    for i in range(n-1):\n        qc.rz(2 * pi * 2**(k_left*i - n + 1), i+2)\n\n    if m_left%2 == 1:\n        qc.x(range(2,n+1))\n        qc.mcx(list(range(2,n)),0)\n        qc.x(range(2,n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 5, "result": "RE", "execution_time": "1460 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.x(range(2,n+1))\n    qc.append(ZGate().control(n), range(n+1))\n    #qc.mcz(range(n),n)\n    qc.x(range(2,n+1))\n\n\n    if m_left%2 == 1: qc.x(0)\n    for i in range(n-1):\n        qc.rz(2 * pi * 2**(k_left*i - n + 1), i+2)\n\n    if m_left%2 == 1:\n        qc.x(range(2,n+1))\n        qc.mcx(list(range(2,n+1)),0)\n        qc.x(range(2,n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 6, "result": "RE", "execution_time": "1601 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    if m_left%2 == 1: qc.x(0)\n    if k_left%2 == 1: qc.x(1)\n    qc.x(range(2,n+1))\n    qc.append(ZGate().control(n), range(n+1))\n    #qc.mcz(range(n),n)\n    qc.x(range(2,n+1))\n    if m_left%2 == 1: qc.x(0)\n    if k_left%2 == 1: qc.x(1)\n\n\n    if m_left%2 == 1: qc.x(0)\n    for i in range(n-1):\n        qc.rz(2 * pi * 2**(k_left*i - n + 1), i+2)\n\n    if m_left%2 == 1:\n        qc.x(range(2,n+1))\n        qc.mcx(list(range(2,n+1)),0)\n        qc.x(range(2,n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 7, "result": "RE", "execution_time": "1584 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.x(range(2,n+1))\n    if m_left%2 == 1 and k_left%2 == 1:\n        qc.append(ZGate().control(n), range(n+1))\n    elif m_left%2 == 1 and k_left%2 == 0:\n        qc.append(ZGate().control(n-1), [0] + list(range(2,n+1)))\n    elif m_left%2 == 0 and k_left%2 == 1:\n        qc.append(ZGate().control(n-1), range(1, n+1))\n    else:\n        qc.append(ZGate().control(n-2), range(2, n+1))\n    #qc.mcz(range(n),n)\n    qc.x(range(2,n+1))\n\n\n    if m_left%2 == 1: qc.x(0)\n    for i in range(n-1):\n        qc.rz(2 * pi * 2**(k_left*i - n + 1), i+2)\n\n    if m_left%2 == 1:\n        qc.x(range(2,n+1))\n        qc.mcx(list(range(2,n+1)),0)\n        qc.x(range(2,n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 8, "result": "RE", "execution_time": "1679 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    qc.x(range(2,n+1))\n    if m_left%2 == 1 and k_left%2 == 1:\n        qc.append(ZGate().control(n), range(n+1))\n    elif m_left%2 == 1 and k_left%2 == 0:\n        qc.append(ZGate().control(n-1), [0] + list(range(2,n+1)))\n    elif m_left%2 == 0 and k_left%2 == 1:\n        qc.append(ZGate().control(n-1), range(1, n+1))\n    else:\n        qc.append(ZGate().control(n-2), range(2, n+1))\n    #qc.mcz(range(n),n)\n    qc.x(range(2,n+1))\n\n\n    if m_left%2 == 1: qc.x(0)\n    for i in range(n-1):\n        qc.rz(2 * pi * 2**(k_left*i - n + 1), i+2)\n\n    #if m_left%2 == 1:\n    #    qc.x(range(2,n+1))\n    #    qc.mcx(list(range(2,n+1)),0)\n    #    qc.x(range(2,n+1))\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 9, "result": "WA", "execution_time": "1704 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    ctrl = [2+s for s in range(n-1)]\n\n    # c に比例する位相回転 ( R^{ck_l} )\n    for s in range(n-1):\n        qc.cp(pi*2 * 2**(s-n+1) * k_left, 2+s, 0)\n    # X^{m_l}\n    if m_left % 2 == 1:\n        qc.x(0)\n        # c=0 に対して x をキャンセル\n        qc.x(ctrl)\n        qc.mcx(ctrl, 0)\n        qc.x(ctrl)\n\n    # c=0 に対して，|a>|b> -> (-1)^{a m_l + b k_l} |a>|b>\n    qc.x(ctrl)\n    if m_left % 2 == 1:\n        qc.mcrz(pi, ctrl, 0)\n    if k_left % 2 == 1:\n        qc.mcrz(pi, ctrl, 1)\n    qc.x(ctrl)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 10, "result": "WA", "execution_time": "1835 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    ctrl = [2+s for s in range(n-1)]\n    # c=0 に対して，|a>|b> -> (-1)^{a m_l + b k_l} |a>|b>\n    qc.x(ctrl)\n    if m_left % 2 == 1:\n        qc.mcrz(pi, ctrl, 0)\n    if k_left % 2 == 1:\n        qc.mcrz(pi, ctrl, 1)\n    qc.x(ctrl)\n\n    # c に比例する位相回転 ( R^{ck_l} )\n    for s in range(n-1):\n        qc.cp(pi*2 * 2**(s-n+1) * k_left, 2+s, 0)\n    # X^{m_l}\n    if m_left % 2 == 1:\n        qc.x(0)\n        # c=0 に対して x をキャンセル\n        #qc.x(ctrl)\n        #qc.mcx(ctrl, 0)\n        #qc.x(ctrl)\n\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 11, "result": "WA", "execution_time": "1884 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    ctrl = [2+s for s in range(n-1)]\n\n    # c=0 に対して，|a>|b> -> (-1)^{a m_l + b k_l} |a>|b>\n    qc.x(ctrl)\n    if m_left % 2 == 1:\n        # qc.mcrz(pi, ctrl, 0)\n        qc.compose(ZGate().control(n-1), ctrl+[0], inplace=True)\n    if k_left % 2 == 1:\n        #qc.mcrz(pi, ctrl, 1)\n        qc.compose(ZGate().control(n-1), ctrl+[1], inplace=True)\n    qc.x(ctrl)\n\n    # c に比例する位相回転 ( R^{ck_l} )\n    for s in range(n-1):\n        qc.cp(pi*2 * 2**(s-n+1) * k_left, 2+s, 0)\n    # X^{m_l}\n    if m_left % 2 == 1:\n        qc.x(0)\n        # c=0 に対して x をキャンセル\n        #qc.x(ctrl)\n        #qc.mcx(ctrl, 0)\n        #qc.x(ctrl)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 12, "result": "WA", "execution_time": "1499 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    ctrl = [2+s for s in range(n-1)]\n\n    # c=0 に対して，|a>|b> -> (-1)^{a m_l + b k_l} |a>|b>\n    qc.x(ctrl)\n    if m_left % 2 == 1:\n        # qc.mcrz(pi, ctrl, 0)\n        qc.compose(ZGate().control(n-1), ctrl+[0], inplace=True)\n    if k_left % 2 == 1:\n        #qc.mcrz(pi, ctrl, 1)\n        qc.compose(ZGate().control(n-1), ctrl+[1], inplace=True)\n    qc.x(ctrl)\n\n    # c に比例する位相回転 ( R^{ck_l} )\n    for s in range(n-1):\n        qc.cp(pi*2 * 2**(s-n+1) * k_left, 2+s, 0)\n    # X^{m_l}\n    if m_left % 2 == 1:\n        qc.x(0)\n        # c=0 に対して x をキャンセル\n        qc.x(ctrl)\n        qc.mcx(ctrl, 0)\n        qc.x(ctrl)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 13, "result": "RE", "execution_time": "1537 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    ctrl = [2+s for s in range(n-1)]\n\n    # c=0 に対して，|a>|b> -> (-1)^{a m_l + b k_l} |a>|b>\n    qc.x(ctrl)\n    if m_left % 2 == 1:\n        # qc.mcrz(pi, ctrl, 0)\n        qc.compose(ZGate().control(n-1), ctrl+[0], inplace=True)\n    if k_left % 2 == 1:\n        #qc.mcrz(pi, ctrl, 1)\n        qc.compose(ZGate().control(n-1), ctrl+[1], inplace=True)\n    qc.x(ctrl)\n\n    # c に比例する位相回転 ( R^{ck_l} )\n    for s in range(n-1):\n        #qc.cp(pi*2 * 2**(s-n+1) * k_left, 2+s, 0)\n        qc.rz(pi*2 * 2**(s-n+1) * k_left, 2+s, 0)\n    # X^{m_l}\n    if m_left % 2 == 1:\n        qc.x(0)\n        # c=0 に対して x をキャンセル\n        qc.x(ctrl)\n        qc.mcx(ctrl, 0)\n        qc.x(ctrl)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A1C722FECC72D", "submission_order": 14, "result": "AC", "execution_time": "2153 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom math import pi\nfrom qiskit.circuit.library import ZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    ctrl = [2+s for s in range(n-1)]\n\n    # c=0 に対して，|a>|b> -> (-1)^{a m_l + b k_l} |a>|b>\n    qc.x(ctrl)\n    if m_left % 2 == 1:\n        # qc.mcrz(pi, ctrl, 0)\n        qc.compose(ZGate().control(n-1), ctrl+[0], inplace=True)\n    if k_left % 2 == 1:\n        #qc.mcrz(pi, ctrl, 1)\n        qc.compose(ZGate().control(n-1), ctrl+[1], inplace=True)\n    qc.x(ctrl)\n\n    # c に比例する位相回転 ( R^{ck_l} )\n    for s in range(n-1):\n        #qc.cp(pi*2 * 2**(s-n+1) * k_left, 2+s, 0)\n        qc.crz(pi*2 * 2**(s-n+1) * k_left, 2+s, 0)\n    # X^{m_l}\n    if m_left % 2 == 1:\n        qc.x(0)\n        # c=0 に対して x をキャンセル\n        qc.x(ctrl)\n        qc.mcx(ctrl, 0)\n        qc.x(ctrl)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A4810BF2F49EE", "submission_order": 1, "result": "WA", "execution_time": "1811 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import ZGate\nimport math\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    if m_left == 1:\n        z0 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z0, list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        z1 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z1, list(range(2, n + 1)) + [1])\n\n    for i in range(n - 1):\n        theta = 2 * math.pi / (2.0 ** (n - 1 - i)) * k_left\n        qc.p(theta, 2 + i)\n\n    if m_left == 1:\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A4810BF2F49EE", "submission_order": 2, "result": "WA", "execution_time": "1852 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\nimport math\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    if m_left == 1:\n        z0 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z0, list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        z1 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z1, list(range(2, n + 1)) + [1])\n\n    for i in range(n - 1):\n        theta = 2 * math.pi / (2.0 ** (n - 1 - i)) * k_left\n        qc.crz(theta, 2 + i, 0)\n\n    x0h = XGate().control(n - 1, ctrl_state=0)\n    qc.append(x0h, list(range(2, n + 1)) + [0])\n    qc.x(0)\n\n    return qc\n\n\ndef main():\n    print(solve(4, 1, 1))\n    # print(solve(4, 2))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_B2", "user": "A4810BF2F49EE", "submission_order": 3, "result": "WA", "execution_time": "1566 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\nimport math\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    if m_left == 1:\n        z0 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z0, list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        z1 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z1, list(range(2, n + 1)) + [1])\n\n    for i in range(n - 1):\n        theta = 2 * math.pi / (2.0 ** (n - 1 - i)) * k_left\n        qc.crz(theta, 2 + i, 0, ctrl_state=0)\n\n    x0h = XGate().control(n - 1, ctrl_state=0)\n    qc.append(x0h, list(range(2, n + 1)) + [0])\n    qc.x(0)\n\n    return qc\n\n\ndef main():\n    print(solve(4, 1, 1))\n    # print(solve(4, 2))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_B2", "user": "A4810BF2F49EE", "submission_order": 4, "result": "WA", "execution_time": "2160 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\nimport math\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    if m_left == 1:\n        z0 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z0, list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        z1 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z1, list(range(2, n + 1)) + [1])\n\n    qc.x(range(2, n + 1))\n    for i in range(n - 1):\n        theta = 2 * math.pi / (2.0 ** (n - 1 - i)) * k_left\n        qc.crz(theta, 2 + i, 0)\n\n    x0h = XGate().control(n - 1, ctrl_state=0)\n    qc.append(x0h, list(range(2, n + 1)) + [0])\n    qc.x(0)\n\n    return qc\n\n\ndef main():\n    print(solve(4, 1, 1))\n    # print(solve(4, 2))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_B2", "user": "A4810BF2F49EE", "submission_order": 5, "result": "AC", "execution_time": "2047 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import XGate, ZGate\nimport math\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    if m_left == 1:\n        z0 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z0, list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        z1 = ZGate().control(n - 1, ctrl_state=0)\n        qc.append(z1, list(range(2, n + 1)) + [1])\n\n    for i in range(n - 1):\n        theta = 2 * math.pi / (2.0 ** (n - 1 - i)) * k_left\n        qc.crz(theta, control_qubit=2 + i, target_qubit=0)\n\n    if m_left == 1:\n        x0h = XGate().control(n - 1, ctrl_state=0)\n        qc.append(x0h, list(range(2, n + 1)) + [0])\n        qc.x(0)\n\n    return qc\n\n\ndef main():\n    print(solve(4, 1, 1))\n    # print(solve(4, 2))\n\n\nif __name__ == \"__main__\":\n    main()\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 1, "result": "RE", "execution_time": "1410 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    k_bits = list()\n\n    for i in range(n):\n        k_bits.append(k_left % 2)\n        k_left >>= 1\n\n    if (m_left == 1):\n        qc.x(0)\n    \n    for i in range(1, n + 1):\n        qc.h(i)\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits(i - 1) * (2 ** (i - 1)) / 2 ** n\n        qc.cp(-theta, 0, i)\n\n    qc.x(0)\n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits(i - 1) * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n\n    qc.x(0)\n    \n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 2, "result": "RE", "execution_time": "1599 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    k_bits = list()\n\n    for i in range(n):\n        k_bits.append(k_left % 2)\n        k_left = k_left // 2\n\n    if (m_left == 1):\n        qc.x(0)\n    \n    for i in range(1, n + 1):\n        qc.h(i)\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits(i - 1) * (2 ** (i - 1)) / 2 ** n\n        qc.cp(-theta, 0, i)\n\n    qc.x(0)\n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits(i - 1) * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n\n    qc.x(0)\n    \n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    k_bits = list()\n\n    for i in range(n):\n        k_bits.append(k_left % 2)\n        k_left = k_left //\n\n    if (m_left == 1):\n        qc.x(0)\n    \n    for i in range(1, n + 1):\n        qc.h(i)\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.cp(-theta, 0, i)\n\n    qc.x(0)\n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n\n    qc.x(0)\n    \n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 4, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    k_bits = list()\n\n    for i in range(n):\n        k_bits.append(k_left % 2)\n        k_left = k_left //\n\n    if (m_left == 1):\n        qc.x(0)\n    \n    for i in range(1, n + 1):\n        qc.h(i)\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.cp(-theta, 0, i)\n\n    qc.x(0)\n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n\n    qc.x(0)\n    \n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 5, "result": "WA", "execution_time": "1781 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    k_bits = list()\n\n    for i in range(n):\n        k_bits.append(k_left % 2)\n        k_left = k_left // 2\n\n    if (m_left == 1):\n        qc.x(0)\n    \n    for i in range(1, n + 1):\n        qc.h(i)\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.cp(-theta, 0, i)\n\n    qc.x(0)\n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n\n    qc.x(0)\n    \n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 6, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    k_bits = list()\n\n    for i in range(n):\n        k_bits.append(k_left % 2)\n        k_left = k_left // \n\n\n    \n    for i in range(1, n + 1):\n        qc.h(i)\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.p(theta, 0, i)\n    \n    for i in range(1, n + 1):\n        theta = -4 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n    \n    if (m_left == 1):\n        qc.x(0)\n\n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 7, "result": "WA", "execution_time": "1590 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    k_bits = list()\n\n    for i in range(n):\n        k_bits.append(k_left % 2)\n        k_left = k_left // 2\n\n\n    \n    for i in range(1, n + 1):\n        qc.h(i)\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.p(theta, i)\n    \n    for i in range(1, n + 1):\n        theta = -4 * math.pi * k_bits[i - 1] * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n    \n    if (m_left == 1):\n        qc.x(0)\n\n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 8, "result": "WA", "execution_time": "1612 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n\n    \n    for i in range(1, n + 1):\n        qc.h(i)\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_left * (2 ** (i - 1)) / 2 ** n\n        qc.p(theta, i)\n    \n    for i in range(1, n + 1):\n        theta = -4 * math.pi * k_left * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n    \n    if (m_left == 1):\n        qc.x(0)\n\n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 9, "result": "WA", "execution_time": "1970 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n\n    \n    QFT(qc, list(range(1, n + 1)))\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_left * (2 ** (i - 1)) / 2 ** n\n        qc.p(theta, i)\n    \n    for i in range(1, n + 1):\n        theta = -4 * math.pi * k_left * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n    \n    if (m_left == 1):\n        qc.x(0)\n\n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 10, "result": "WA", "execution_time": "1581 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n\n    \n    QFT(qc, list(range(1, n + 1)))\n    \n    for i in range(1, n + 1):\n        theta = 2 * math.pi * k_left * (2 ** (i - 1)) / 2 ** n\n        qc.p(theta, i)\n    \n    for i in range(1, n + 1):\n        theta = -4 * math.pi * k_left * (2 ** (i - 1)) / 2 ** n\n        qc.cp(theta, 0, i)\n\n    QFT(qc, list(range(1, n + 1)), inversed=True)\n\n    if (m_left == 1):\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 11, "result": "WA", "execution_time": "1857 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.rz(2 * math.pi * k_left / (2 **(n - 1)), 0)\n    \n    if (m_left == 1):\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 12, "result": "WA", "execution_time": "1682 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.rz(2 * math.pi * k_left / (2 **(n)), 0)\n    \n    if (m_left == 1):\n        qc.x(0)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 13, "result": "WA", "execution_time": "1582 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.rz(2 * math.pi * k_left / (2 **(n - 1)), 0)\n    \n    if (m_left == 1):\n        qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 14, "result": "RE", "execution_time": "1710 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(2, n + 1):\n        qc.x(i)\n    qc.mcp(math.pi * m_left, list(range(2, n + 1)), 0)\n    qc.mcp(math.pi * k_left, list(range(2, n + 1)), 1)\n    qc.mcrz(-2 * math.pi * k_left / (2 ** (n - 1)), list(range(2, n + 1)), 0)\n    \n    \n\n    qc.rz(2 * math.pi * k_left / (2 **(n - 1)), 0)\n    \n    if (m_left == 1):\n        qc.mcz(list(range(2, n+1)), 0)\n        qc.z(0)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 15, "result": "WA", "execution_time": "1587 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(2, n + 1):\n        qc.x(i)\n    qc.mcp(math.pi * m_left, list(range(2, n + 1)), 0)\n    qc.mcp(math.pi * k_left, list(range(2, n + 1)), 1)\n    qc.mcrz(-2 * math.pi * k_left / (2 ** (n - 1)), list(range(2, n + 1)), 0)\n    \n    \n\n    qc.rz(2 * math.pi * k_left / (2 **(n - 1)), 0)\n    \n    if (m_left == 1):\n        qc.mcp(math.pi, list(range(2, n+1)), 0)\n        \n    for i in range(2, n + 1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 16, "result": "WA", "execution_time": "1640 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(2, n + 1):\n        qc.x(i)\n    qc.mcp(math.pi * m_left, list(range(2, n + 1)), 0)\n    qc.mcp(math.pi * k_left, list(range(2, n + 1)), 1)\n    qc.mcrz(-2 * math.pi * k_left / (2 ** (n - 1)), list(range(2, n + 1)), 0)\n    \n    \n\n    qc.rz(2 * math.pi * k_left / (2 **(n - 1)), 0)\n    \n    if (m_left == 1):\n        qc.mcp(2 *  math.pi,list(range(2, n+1)), 0)\n        \n    for i in range(2, n + 1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A59B8A5A9E621", "submission_order": 17, "result": "WA", "execution_time": "1752 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import HGate, ZGate, XGate, PhaseGate\nfrom qiskit import QuantumRegister\nimport math\n\ndef QFT(qc : QuantumCircuit, idx : list[int], inversed : bool = False) -> QuantumCircuit:\n    n = len(idx)\n    for i in range(n // 2):\n        qc.swap(idx[i], idx[n - i - 1])\n    for j in range(n):\n        qc.h(idx[j])\n        for k in range(j+1, n):\n            theta = math.pi / (2 ** (k - j))\n            if (inversed):\n                theta *= -1\n            qc.cp(theta, idx[k], idx[j])\n\n    #for i in range(n // 2):\n    #    qc.swap(idx[i], idx[n - i - 1])\n\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(2, n + 1):\n        qc.x(i)\n    qc.mcp(math.pi * m_left, list(range(2, n + 1)), 0)\n    qc.mcp(math.pi * k_left, list(range(2, n + 1)), 1)\n    qc.mcrz(-2 * math.pi * k_left / (2 ** (n - 1)), list(range(2, n + 1)), 0)\n    \n    \n\n    qc.rz(2 * math.pi * k_left / (2 **(n - 1)), 0)\n    \n    if (m_left == 1):\n        qc.z(0)\n        qc.mcp(2 *  math.pi,list(range(2, n+1)), 0)\n        \n    for i in range(2, n + 1):\n        qc.x(i)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A5E2D9864291A", "submission_order": 1, "result": "WA", "execution_time": "1455 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, RZGate\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.x(range(2, n + 1))\n\n    S = [k_left * (2 ** i) for i in range(n)]\n    for i in range(n):\n        theta = 2 * pi * S[i] / 2**n\n        qc.p(theta, i)    \n    if m_left == 1:\n      qc.x(0)\n    if m_left == 1:\n      qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [0])\n    qc.x(range(2, n + 1))\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A5E2D9864291A", "submission_order": 2, "result": "WA", "execution_time": "1695 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, RZGate\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.x(range(2, n + 1))\n\n    S = [k_left * (2 ** i) for i in range(n - 1)]\n    for i in range(n - 1):\n        theta = 2 * pi * S[i] / 2**n\n        qc.cp(theta, i + 2, 0)\n\n    if m_left == 1:\n      qc.x(0)\n    if m_left == 1:\n      qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [0])\n\n    qc.x(range(2, n + 1))\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A5E2D9864291A", "submission_order": 3, "result": "WA", "execution_time": "1526 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, RZGate\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.x(range(2, n + 1))\n\n    S = [k_left * (2 ** i) for i in range(n - 1)]\n    for i in range(n - 1):\n        theta = 2 * pi * S[i] / 2**n\n        qc.crz(theta, i + 2, 0)\n\n    if m_left == 1:\n      qc.x(0)\n    if m_left == 1:\n      qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [0])\n\n    qc.x(range(2, n + 1))\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A5E2D9864291A", "submission_order": 4, "result": "WA", "execution_time": "1469 ms", "memory": "144 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, RZGate\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.x(range(2, n + 1))\n\n    S = [k_left * (2 ** i) for i in range(n - 1)]\n    for i in range(n - 1):\n        theta = 2 * pi * S[i] / 2**(n - 1)\n        qc.crz(theta, i + 2, 0)\n\n    if m_left == 1:\n      qc.x(0)\n    if m_left == 1:\n      qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [0])\n\n    qc.x(range(2, n + 1))\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A5E2D9864291A", "submission_order": 5, "result": "WA", "execution_time": "1628 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, RZGate\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    S = [k_left * (2 ** i) for i in range(n - 1)]\n    for i in range(n - 1):\n        theta = 2 * pi * S[i] / 2**(n - 1)\n        qc.crz(theta, i + 2, 0)\n\n    qc.x(range(2, n + 1))\n\n    if m_left == 1:\n      qc.x(0)\n    if m_left == 1:\n      qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [0])\n\n    qc.x(range(2, n + 1))\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A5E2D9864291A", "submission_order": 6, "result": "WA", "execution_time": "1621 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library.standard_gates import XGate, ZGate\nfrom math import pi\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.x(range(2, n + 1))\n    if m_left == 1:\n      qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [0])\n    if k_left%2 == 1:\n      qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [1])\n\n    S = [k_left * (2 ** i) for i in range(n - 1)]\n    for i in range(n - 1):\n        theta = 2 * pi * S[i] / 2**(n - 1)\n        qc.crz(theta, i + 2, 0)\n\n    if m_left == 1:\n      qc.x(0)\n    if m_left == 1:\n      qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [0])\n\n    qc.x(range(2, n + 1))\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 1, "result": "WA", "execution_time": "1476 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / 2 ** (n - 1)\n\n    qc.x(anc)\n    qc.mcx(c, anc)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.mcrz(zangle * (2**i), anc, c[i])\n\n    qc.mcx(c, anc)\n    qc.x(anc)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 2, "result": "WA", "execution_time": "1626 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / 2 ** (n - 1)\n\n    qc.x(anc)\n    qc.mcx(c, anc)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.mcrz(zangle * k_left * (2**i), anc, c[i])\n\n    qc.mcx(c, anc)\n    qc.x(anc)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 3, "result": "WA", "execution_time": "1679 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n    )\n\n    qc = QuantumCircuit(a, b, c)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.rz(zangle * k_left * (2**i), c[i])\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 4, "result": "RE", "execution_time": "1379 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    qc.x(anc)\n    qc.mcx(c, anc)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), anc, a)\n\n    qc.mcx(c, anc)\n    qc.x(anc)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 5, "result": "WA", "execution_time": "1584 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    qc.x(anc)\n    qc.mcx(c, anc)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), anc, a)\n\n    qc.mcx(c, anc)\n    qc.x(anc)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 6, "result": "WA", "execution_time": "1692 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n    )\n\n    qc = QuantumCircuit(a, b, c)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 7, "result": "WA", "execution_time": "1687 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import HGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    qc.x(c)\n    qc.x(anc)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    else:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n        qc.cx(anc, a)\n\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 8, "result": "WA", "execution_time": "1488 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    qc.x(c)\n    qc.x(anc)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    else:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n        qc.cx(anc, a)\n\n    qc.x(c)\n\n    # 11\n    if (m_left + k_left) % 2 == 1:\n        qc.append(ZGate().control(1), [*a, *b])\n\n    qc.x(a)\n    # 01\n    if (k_left) % 2 == 1:\n        qc.append(ZGate().control(1), [*a, *b])\n\n    qc.x(a)\n    qc.x(b)\n    # 10\n    if (m_left) % 2 == 1:\n        qc.append(ZGate().control(1), [*a, *b])\n\n    qc.x(b)\n\n    qc.mcx(c, anc)\n    qc.x(anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 9, "result": "WA", "execution_time": "1570 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    qc.x(c)\n    qc.x(anc)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    else:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n        qc.cx(anc, a)\n\n    qc.x(c)\n\n    # 11\n    if (m_left + k_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(a)\n    # 01\n    if (k_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(a)\n    qc.x(b)\n    # 10\n    if (m_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(b)\n\n    qc.mcx(c, anc)\n    qc.x(anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 10, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    qc.x(c)\n    qc.x(anc)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    else:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n        qc.cx(anc, a)\n\n    qc.x(anc)\n\n    # 11\n    if (m_left + k_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(a)\n    # 01\n    if (k_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(a)\n    qc.x(b)\n    # 10\n    if (m_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(b)\n\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\n## test here\nimport qutils\n\ncv = qutils.CircuitViewer(solve(3, 1, 1))\n\ncv.draw()\n# cv.print_mapping()\n'''"}
{"problem": "QPC005_B2", "user": "A604BC7EFCD4D", "submission_order": 11, "result": "AC", "execution_time": "2064 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    qc.x(c)\n    qc.x(anc)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    if m_left == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    else:\n        for i in range(n - 1):\n            qc.crz(zangle * k_left * (2**i), c[i], a)\n\n        qc.cx(anc, a)\n\n    qc.x(anc)\n\n    # 11\n    if (m_left + k_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(a)\n    # 01\n    if (k_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(a)\n    qc.x(b)\n    # 10\n    if (m_left) % 2 == 1:\n        qc.append(ZGate().control(2), [*a, *b, *anc])\n\n    qc.x(b)\n\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A6E6E157055EB", "submission_order": 1, "result": "RE", "execution_time": "1812 ms", "memory": "142 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, RZGate\n\ndef A3(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c = QuantumRegister(1), QuantumRegister(1), QuantumRegister(n - 1)\n    qc = QuantumCircuit(a, b, c)\n    # Write your code here:\n    qc.x(c)\n    if m_left:\n        qc.compose(ZGate().control(len(c)),[*c, *a])\n    if k_left % 2:\n        qc.compose(ZGate().control(len(c)),[*c, *b])\n    qc.x(c)\n    for i in range(n - 1):\n        qc.compose(RZGate(2 ** (2 - n + i) * math.pi).control(1),[*c, *a])\n    if m_left:\n        qc.compose(A3(n - 1) ,[a[0], *c], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A6E6E157055EB", "submission_order": 2, "result": "RE", "execution_time": "1606 ms", "memory": "140 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, RZGate\n\ndef A3(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c = QuantumRegister(1), QuantumRegister(1), QuantumRegister(n - 1)\n    qc = QuantumCircuit(a, b, c)\n    # Write your code here:\n    qc.x(c)\n    if m_left:\n        qc.compose(ZGate().control(len(c)),[*c, *a])\n    if k_left % 2:\n        qc.compose(ZGate().control(len(c)),[*c, *b])\n    qc.x(c)\n    for i in range(n - 1):\n        qc.compose(RZGate(2 ** (2 - n + i) * k_left * math.pi).control(1),[*c, *a])\n    if m_left:\n        qc.compose(A3(n - 1), [a[0], *c], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A6E6E157055EB", "submission_order": 3, "result": "AC", "execution_time": "2058 ms", "memory": "145 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, RZGate\n\ndef A3(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m)\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c = QuantumRegister(1), QuantumRegister(1), QuantumRegister(n - 1)\n    qc = QuantumCircuit(a, b, c)\n    # Write your code here:\n    qc.x(c)\n    if m_left:\n        qc.compose(ZGate().control(len(c)), [*c, a[0]], inplace=True)\n    if k_left % 2:\n        qc.compose(ZGate().control(len(c)), [*c, b[0]], inplace=True)\n    qc.x(c)\n    for i in range(n - 1):\n        qc.compose(RZGate(2 ** (2 - n + i) * k_left * math.pi).control(1), [c[i], a[0]], inplace=True)\n    if m_left:\n        qc.compose(A3(n - 1), [a[0], *c], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A77AC6C9BCE6D", "submission_order": 1, "result": "WA", "execution_time": "1651 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(1, n + 1):\n        angle = 2 * math.pi / (2**n) * k_left * (2**(i - 1))\n        qc.p(angle, i)\n        qc.cp(-angle * 2, 0, i)\n\n    angle = 2 * math.pi / 2 * m_left\n    qc.p(angle, 0)\n \n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A77AC6C9BCE6D", "submission_order": 2, "result": "WA", "execution_time": "1613 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    for i in range(1, n + 1):\n        angle = 2 * math.pi / (2**n) * k_left * (2**(i - 1))\n        qc.p(-angle, i)\n        qc.cp(angle * 2, 0, i)\n\n    angle = 2 * math.pi / 2 * m_left\n    qc.p(angle, 0)\n \n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A77AC6C9BCE6D", "submission_order": 3, "result": "WA", "execution_time": "1603 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    angle = 2 * math.pi / 2 * m_left\n    qc.p(angle, 0)\n\n    for i in range(1, n + 1):\n        angle = 2 * math.pi / (2**n) * k_left * (2**(i - 1))\n        qc.p(angle, i)\n        qc.cp(-angle * 2, 0, i)\n \n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A77FC0E7E5F60", "submission_order": 1, "result": "RE", "execution_time": "1396 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    if m_left == 1:\n        qc.x(m[0])\n\n    # 2. kレジスタにk_left加算 or -k_left加算（m制御）\n    if k_left != 0:\n        # m = 0 のとき加算, m = 1 のとき減算\n        # a. m=0: kに+k_left\n        qc.mcx([m[0]], k[0])  # m[0]=1のときのみ作用\n        for i in range(n):\n            if (k_left >> i) & 1:\n                qc.cx(m[0], k[i])\n        qc.mcx([m[0]], k[0])  # 戻す\n\n        # b. m=1: kに-k_left（= 2^n - k_left加算）\n        # (m[0]=1 の時にだけk_leftを差し引く加算を行う)\n        for i in range(n):\n            if (k_left >> i) & 1:\n                qc.cx(m[0], k[i])\n\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A77FC0E7E5F60", "submission_order": 2, "result": "WA", "execution_time": "1670 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    m = n  # mは最上位ビット、kは下位nビット\n\n    # 1. mレジスタのXOR（CNOT）\n    if m_left == 1:\n        qc.x(m)\n\n    # 2. kレジスタに制御加算・減算\n    # まず m==0 のとき加算 (Xで反転して制御→加算→戻す)\n    qc.x(m)\n    for i in range(n):\n        if (k_left >> i) & 1:\n            qc.cx(m, i)\n    qc.x(m)\n    # 次に m==1 のとき減算 (そのまま加算: -k_left = 2^n - k_left)\n    if k_left != 0:\n        for i in range(n):\n            if (k_left >> i) & 1:\n                qc.cx(m, i)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 1, "result": "UME", "execution_time": "", "memory": "", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\nimport numpy as np\nfrom qiskit import QuantumCircuit\nfrom qiskit.circuit.library import QFT\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    k_qubits = list(range(n))\n    m_qubit = n\n    qc.compose(qft(n), k_qubits, inplace=True)\n\n    for i in range(n):\n        angle = (2 * np.pi * k_left) / (2**(i + 1))\n        if angle != 0:\n            qc.p(angle, k_qubits[i])\n\n    qc.compose(qft(n).inverse(), k_qubits, inplace=True)\n    \n    qc.compose(qft(n), k_qubits, inplace=True)\n\n    for i in range(n):\n        angle = -(2 * np.pi * (2 * k_left)) / (2**(i + 1))\n        if angle != 0:\n            qc.cp(angle, m_qubit, k_qubits[i])\n            \n    qc.compose(qft(n).inverse(), k_qubits, inplace=True)\n\n    if m_left == 1:\n        qc.x(m_qubit)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 2, "result": "WA", "execution_time": "1566 ms", "memory": "142 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\n\ndef qft(n: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n)\n \n    for i in reversed(range(n)):\n        qc.h(i)\n        for j in reversed(range(i)):\n            qc.cp(pi / 2 ** (i - j), j, i)\n \n    for i in range(n // 2):\n        qc.swap(i, n - i - 1)\n \n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    k_qubits = list(range(n))\n    m_qubit = n\n    qc.compose(qft(n), k_qubits, inplace=True)\n\n    for i in range(n):\n        angle = (2 * np.pi * k_left) / (2**(i + 1))\n        if angle != 0:\n            qc.p(angle, k_qubits[i])\n\n    qc.compose(qft(n).inverse(), k_qubits, inplace=True)\n    \n    qc.compose(qft(n), k_qubits, inplace=True)\n\n    for i in range(n):\n        angle = -(2 * np.pi * (2 * k_left)) / (2**(i + 1))\n        if angle != 0:\n            qc.cp(angle, m_qubit, k_qubits[i])\n            \n    qc.compose(qft(n).inverse(), k_qubits, inplace=True)\n\n    if m_left == 1:\n        qc.x(m_qubit)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 3, "result": "RE", "execution_time": "", "memory": "", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RzGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    t=2 *pi / 2**(n-1)\n    qc.rz(t,1)\n    # Write your code here:\n    for i in range(2:n+1):\n        qc.x(0)\n    qc.mcx(list(range(2:n+1)),0)\n    qrz = RzGate(2*pi - t).control(n-1)\n    qc.append(qrz,qc[2:n+1],qc[0:2])\n    for i in range(2:n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 4, "result": "RE", "execution_time": "1556 ms", "memory": "141 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    t=2 *pi / 2**(n-1)\n    qc.rz(t,1)\n    # Write your code here:\n    for i in range(2,n+1):\n        qc.x(0)\n    qc.mcx(list(range(2,n+1)),0)\n    qrz = RzGate(2*pi - t).control(n-1)\n    qc.append(qrz,qc[2:n+1],qc[0:2])\n    for i in range(2,n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 5, "result": "RE", "execution_time": "1495 ms", "memory": "140 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    t=2 *pi / 2**(n-1)\n    qc.rz(t,1)\n    # Write your code here:\n    for i in range(2,n+1):\n        qc.x(0)\n    qc.mcx(list(range(2,n+1)),0)\n    qrz = RZGate(2*pi - t).control(n-1)\n    qc.append(qrz,qc[2:n+1],qc[0:2])\n    for i in range(2,n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 6, "result": "RE", "execution_time": "1490 ms", "memory": "140 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    t=2 *pi / 2**(n-1)\n    qc.rz(t,1)\n    # Write your code here:\n    for i in range(2,n+1):\n        qc.x(0)\n    qc.mcx(list(range(2,n+1)),0)\n    qrz = RZGate(2*pi - t).control(n-1)\n    qc.append(qrz,qc[2:n+1]+qc[0:2])\n    for i in range(2,n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 7, "result": "WA", "execution_time": "1964 ms", "memory": "143 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    t=2 *pi *k_left / 2**(n-1)\n    qc.rz(t,1)\n    # Write your code here:\n    for i in range(2,n+1):\n        qc.x(0)\n    qc.mcx(list(range(2,n+1)),0)\n    qrz = RZGate(2*pi - t).control(n-1)\n    control_qubits = list(range(2, n + 1))\n    target_qubit = 1\n    qc.append(qrz, control_qubits + [target_qubit])\n    for i in range(2,n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 8, "result": "RE", "execution_time": "1467 ms", "memory": "141 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    for i in range(2,n+1):\n        t=2 *pi *k_left * 2**(i-2) / 2**(n-1)\n        qc.crz(t,i,1)\n    qc.append(qrz, control_qubits + [target_qubit])\n    # Write your code here:\n    for i in range(2,n+1):\n        qc.x(0)\n    qc.mcx(list(range(2,n+1)),0)\n    qc.append(qrz, control_qubits + [target_qubit])\n    for i in range(2,n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 9, "result": "RE", "execution_time": "1460 ms", "memory": "141 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    for i in range(2,n+1):\n        t=2 *pi *k_left * 2**(i-2) / 2**(n-1)\n        qc.crz(t,i,1)\n    qc.append(qrz, control_qubits + [target_qubit])\n    # Write your code here:\n    for i in range(2,n+1):\n        qc.x(0)\n    qc.mcx(list(range(2,n+1)),0)\n    for i in range(2,n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 10, "result": "WA", "execution_time": "1610 ms", "memory": "142 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    for i in range(2,n+1):\n        t=2 *pi *k_left * 2**(i-2) / 2**(n-1)\n        qc.crz(t,i,1)\n    # Write your code here:\n    for i in range(2,n+1):\n        qc.x(0)\n    qc.mcx(list(range(2,n+1)),0)\n    for i in range(2,n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "A7BAA68F1802F", "submission_order": 11, "result": "WA", "execution_time": "1669 ms", "memory": "142 MiB", "code": "'''python\nfrom math import ceil,floor,acos,asin,atan,sqrt,pi,gcd,sin,cos,tan,log2\nimport numpy as np\nfrom qiskit import QuantumCircuit,QuantumRegister\nfrom qiskit.circuit.library import RZGate\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    if m_left==1:\n        qc.x(0)\n    for i in range(2,n+1):\n        t=2 *pi *k_left * 2**(i-2) / 2**(n-1)\n        qc.crz(t,i,1)\n    # Write your code here:\n    for i in range(2,n+1):\n        qc.x(0)\n    if m_left==1:\n        qc.mcx(list(range(2,n+1)),0)\n    for i in range(2,n+1):\n        qc.x(0)\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AAC0A0DA56508", "submission_order": 1, "result": "WA", "execution_time": "1652 ms", "memory": "143 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate, RZGate\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    # now qubit 1 is exactly m\n    qc.cx(1, 0)\n    ###\n\n    # rotate qubit 0 by (-1)^m c k_left\n    for i in range(n - 1):\n        theta = 2 * math.pi * k_left * 2 ** i / 2 ** (n - 1)\n        qc.append(RZGate(-theta).control(1), [i + 2, 0])\n        qc.append(RZGate(theta * 2).control(2), [i + 2, 1, 0])\n    if m_left == 1:\n        qc.x(1)\n\n    ###\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AAC0A0DA56508", "submission_order": 2, "result": "WA", "execution_time": "1724 ms", "memory": "145 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate, RZGate\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    # now qubit 1 is exactly m\n    qc.cx(1, 0)\n    ###\n\n    # rotate qubit 0 by (-1)^m c k_left\n    for i in range(n - 1):\n        theta = 2 * math.pi * k_left * 2 ** i / 2 ** (n - 1)\n        qc.append(RZGate(-theta).control(1), [i + 2, 0])\n        qc.append(RZGate(theta * 2).control(2), [i + 2, 1, 0])\n\n    if m_left == 1:\n        qc.x(range(2, n + 1))\n        qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [1])\n        qc.x(range(2, n + 1))\n\n    ###\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    qc.x(range(2, n + 1))\n    if m_left == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [1])\n    qc.x(range(2, n + 1))\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AAC0A0DA56508", "submission_order": 3, "result": "WA", "execution_time": "1536 ms", "memory": "145 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate, RZGate\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    # now qubit 1 is exactly m\n    qc.cx(1, 0)\n    ###\n\n    # rotate qubit 0 by (-1)^m c k_left\n    for i in range(n - 1):\n        theta = 2 * math.pi * k_left * 2 ** i / 2 ** (n - 1)\n        qc.append(RZGate(theta).control(1), [i + 2, 0])\n        qc.append(RZGate(-theta * 2).control(2), [i + 2, 1, 0])\n\n    if m_left == 1:\n        qc.x(range(2, n + 1))\n        qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [1])\n        qc.x(range(2, n + 1))\n\n    ###\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    qc.x(range(2, n + 1))\n    if m_left == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [1])\n    qc.x(range(2, n + 1))\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AAC0A0DA56508", "submission_order": 4, "result": "WA", "execution_time": "1627 ms", "memory": "142 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate, RZGate\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    # now qubit 1 is exactly m\n    qc.cx(1, 0)\n    ###\n\n    # rotate qubit 0 by (-1)^m c k_left\n    for i in range(n - 1):\n        theta = 2 * math.pi * k_left * 2 ** i / 2 ** (n - 1)\n        qc.append(RZGate(-theta).control(2), [i + 2, 1, 0])\n        qc.x(1)\n        qc.append(RZGate(theta).control(2), [i + 2, 1, 0])\n        qc.x(1)\n\n    if m_left == 1:\n        qc.x(range(2, n + 1))\n        qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [1])\n        qc.x(range(2, n + 1))\n\n    ###\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    qc.x(range(2, n + 1))\n    if m_left == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [1])\n    qc.x(range(2, n + 1))\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AAC0A0DA56508", "submission_order": 5, "result": "RE", "execution_time": "1498 ms", "memory": "141 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate, RZGate\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    # now qubit 1 is exactly m\n    qc.cx(1, 0)\n    ###\n\n    # rotate qubit 0 by (-1)^m c k_left\n    for i in range(n - 1):\n        theta = 2 * math.pi * k_left * 2 ** i / 2 ** n\n        qc.append(RZGate(-theta).control(2), [i + 2, 1, 0])\n        # qc.x(1)\n        qc.append(RZGate(theta * 2).control(2), [i + 2, 0])\n        # qc.x(1)\n\n    # apply X^m_left\n    if m_left == 1:\n        qc.x(range(2, n + 1))\n        qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [1])\n        qc.x(range(2, n + 1))\n\n    ###\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    qc.x(range(2, n + 1))\n    if m_left == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [1])\n    qc.x(range(2, n + 1))\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AAC0A0DA56508", "submission_order": 6, "result": "WA", "execution_time": "1631 ms", "memory": "146 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate, RZGate\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    # now qubit 1 is exactly m\n    qc.cx(1, 0)\n    ###\n\n    # rotate qubit 0 by (-1)^m c k_left\n    for i in range(n - 1):\n        theta = 2 * math.pi * k_left * 2 ** i / 2 ** n\n        qc.append(RZGate(-theta).control(2), [i + 2, 1, 0])\n        # qc.x(1)\n        qc.append(RZGate(theta * 2).control(1), [i + 2, 0])\n        # qc.x(1)\n\n    # apply X^m_left\n    if m_left == 1:\n        qc.x(range(2, n + 1))\n        qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [1])\n        qc.x(range(2, n + 1))\n\n    ###\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    qc.x(range(2, n + 1))\n    if m_left == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [1])\n    qc.x(range(2, n + 1))\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AAC0A0DA56508", "submission_order": 7, "result": "WA", "execution_time": "1552 ms", "memory": "146 MiB", "code": "'''python\nimport math\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import ZGate, XGate, HGate, SwapGate, RZGate\n \ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    qc.cx(0, 1)\n    # now qubit 1 is exactly m\n    qc.cx(1, 0)\n    ###\n\n    # rotate qubit 0 by (-1)^m c k_left\n    for i in range(n - 1):\n        theta = 2 * math.pi * k_left * 2 ** i / 2 ** n\n        qc.append(RZGate(theta).control(2), [i + 2, 1, 0])\n        # qc.x(1)\n        qc.append(RZGate(-theta * 2).control(1), [i + 2, 0])\n        # qc.x(1)\n\n    # apply X^m_left\n    if m_left == 1:\n        qc.x(range(2, n + 1))\n        qc.append(XGate().control(n - 1), list(range(2, n + 1)) + [1])\n        qc.x(range(2, n + 1))\n\n    ###\n    qc.cx(1, 0)\n    qc.cx(0, 1)\n\n    qc.x(range(2, n + 1))\n    if m_left == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [0])\n    if k_left % 2 == 1:\n        qc.append(ZGate().control(n - 1), list(range(2, n + 1)) + [1])\n    qc.x(range(2, n + 1))\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AEC42DC0B4668", "submission_order": 1, "result": "WA", "execution_time": "1622 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate, RZGate\n\n# def B1(n: int, k_const: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     for i in range(n):\n#         qc.append(PhaseGate(2 * pi / (1 << n) * k_const), [i])\n#         k_const *= 2\n#         k_const %= (1 << n)\n    \n#     return qc\n\n# X を通すと回転量が -1 倍\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n    N = n - 1\n    for i in range(N):\n        qc.append(RZGate(2 * pi / (1 << n) * k_left).control(1), [i + 2, 0])\n        k_left *= 2\n        k_left %= (1 << n)\n    if m_left:\n        qc.x(0)\n        qc.append(XGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n    if k_left & 1:\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AEC42DC0B4668", "submission_order": 2, "result": "AC", "execution_time": "1777 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate, RZGate\n\n# def B1(n: int, k_const: int) -> QuantumCircuit:\n#     qc = QuantumCircuit(n)\n#     for i in range(n):\n#         qc.append(PhaseGate(2 * pi / (1 << n) * k_const), [i])\n#         k_const *= 2\n#         k_const %= (1 << n)\n    \n#     return qc\n\n# X を通すと回転量が -1 倍\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # qc.x(0)\n    # qc.x(1)\n    # qc.x(2)\n    # Write your code here:\n    N = n - 1\n    k = k_left\n    for i in range(N):\n        qc.append(RZGate(2 * pi / (1 << N) * k).control(1), [i + 2, 0])\n        k *= 2\n        k %= (1 << n)\n    if m_left:\n        qc.x(0)\n        qc.append(XGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n    if k_left & 1:\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [1])\n\n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AF959EEC7F235", "submission_order": 1, "result": "WA", "execution_time": "1802 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n    if m_left == 1:\n        qc.x(n)\n    \n    if k_left != 0:\n        angle = 2 * 3.14159265359 / (2**(n-1)) * k_left\n        qc.rz(angle, 0)\n    \n    for i in range(n):\n        if k_left != 0:\n            angle = 2 * 3.14159265359 / (2**(n-1)) * k_left\n            qc.crz(-2*angle, n, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AF959EEC7F235", "submission_order": 2, "result": "WA", "execution_time": "1625 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n    if m_left == 1:\n        qc.x(n)\n    \n    if k_left != 0:\n        angle = 2 * 3.14159265359 * k_left / (2**n)\n        \n        for i in range(n):\n            qc.rz(angle / (2**i), i)\n        \n        for i in range(n):\n            qc.cx(n, i)\n            qc.rz(-angle / (2**i), i)\n            qc.cx(n, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_B2", "user": "AF959EEC7F235", "submission_order": 3, "result": "WA", "execution_time": "1598 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    \n    # Apply X gate to control qubit if m_left = 1\n    if m_left == 1:\n        qc.x(n)\n    \n    # Apply controlled rotation gates if k_left != 0\n    if k_left != 0:\n        angle = 2 * 3.14159265359 * k_left / (2**n)\n        \n        # Apply rotation gates to target qubits\n        for i in range(n):\n            qc.rz(angle / (2**i), i)\n        \n        # Apply controlled rotation gates\n        for i in range(n):\n            qc.cx(n, i)\n            qc.rz(-angle / (2**i), i)\n            qc.cx(n, i)\n    \n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "A85063FEE6740", "submission_order": 1, "result": "WA", "execution_time": "1798 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # Write your code here:\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "A9B0542AAB32E", "submission_order": 1, "result": "AC", "execution_time": "1922 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit\nimport math\n\ndef _negctrl_x(qc: QuantumCircuit, ctrls, tgt):\n\n    if not ctrls:                       \n        qc.x(tgt)\n        return\n\n    for q in ctrls:\n        qc.x(q)                         \n    qc.mcx(ctrls, tgt)                   \n    for q in ctrls:\n        qc.x(q)                          \n\n\ndef _negctrl_z(qc: QuantumCircuit, ctrls, tgt):\n    if not ctrls:\n        qc.z(tgt)\n        return\n\n    for q in ctrls:\n        qc.x(q)\n    qc.h(tgt)\n    qc.mcx(ctrls, tgt)                   \n    qc.h(tgt)\n    for q in ctrls:\n        qc.x(q)\n\ndef solve(n: int, m_right: int, k_right: int):\n\n    qc = QuantumCircuit(n + 1)\n\n    a, b = 0, 1\n    c_qubits = list(range(2, n + 1))          \n    base_angle = 2 * math.pi / (1 << (n - 1))  \n\n    if m_right & 1:\n        qc.x(b)                              \n        _negctrl_x(qc, c_qubits, b)           \n\n    k_mod = k_right % (1 << n)                \n    if k_mod:\n        for j, cq in enumerate(c_qubits):     \n            exponent = (k_mod * (1 << j)) % (1 << n)   \n            if exponent == 0:\n                continue                      \n            angle = exponent * base_angle\n            qc.crz(angle, cq, b)\n\n    if m_right & 1:\n        _negctrl_z(qc, c_qubits, a)           \n    if k_right & 1:\n        _negctrl_z(qc, c_qubits, b)           \n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "ABC141F00433E", "submission_order": 1, "result": "WA", "execution_time": "1754 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate, RZGate\n\n# X を通すと回転量が -1 倍\n# X がかかっているかどうかを取得しないといけないのか\n# X = 0 なら， R^{k} -> R^{k + kr} or R^{k - kr}\n# X = 1 なら， R^{-k} -> R^{-k - kr} or R^{-k + kr}\n# |01> と |11> を +kr 倍， |00> と |10> を -kr 倍したい\n# 1 bit 目にあるじゃん\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # qc.x(0)\n    # qc.x(1)\n    # qc.x(2)\n    # Write your code here:\n    N = n - 1\n    k = k_left\n    qc.cx(0, 1)\n    for i in range(N):\n        qc.append(RZGate(2 * pi / (1 << N) * k).control(1), [i + 2, 1])\n        k *= 2\n        k %= (1 << n)\n    if m_left:\n        qc.x(0)\n        qc.append(XGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n    if k_left & 1:\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [1])\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "ABC141F00433E", "submission_order": 2, "result": "WA", "execution_time": "1569 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate, RZGate\n\n# X を通すと回転量が -1 倍\n# X がかかっているかどうかを取得しないといけないのか\n# X = 0 なら， R^{k} -> R^{k + kr} or R^{k - kr}\n# X = 1 なら， R^{-k} -> R^{-k - kr} or R^{-k + kr}\n# |01> と |11> を +kr 倍， |00> と |10> を -kr 倍したい\n# 1 bit 目にあるじゃん\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # qc.x(0)\n    # qc.x(1)\n    # qc.x(2)\n    # Write your code here:\n    N = n - 1\n    k = k_left\n    if m_left:\n        k *= -1\n    for i in range(N):\n        qc.append(RZGate(2 * pi / (1 << N) * k).control(1), [i + 2, 1])\n        k *= 2\n        k %= (1 << n)\n    if m_left:\n        qc.x(0)\n        qc.append(XGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n    if k_left & 1:\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [1])\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "ABC141F00433E", "submission_order": 3, "result": "WA", "execution_time": "1687 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate, RZGate\n\n# X を通すと回転量が -1 倍\n# X がかかっているかどうかを取得しないといけないのか\n# X = 0 なら， R^{k} -> R^{k + kr} or R^{k - kr}\n# X = 1 なら， R^{-k} -> R^{-k - kr} or R^{-k + kr}\n# Xr = 0 のとき，|01> と |11> を +kr 倍， |00> と |10> を -kr 倍したい\n# 1 bit 目にあるじゃん\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # qc.x(0)\n    # qc.x(1)\n    # qc.x(2)\n    # qc.x(3)\n    # Write your code here:\n    N = n - 1\n    k = k_left\n    for i in range(N):\n        qc.append(RZGate(2 * pi / (1 << N) * k).control(1), [i + 2, 1])\n        k *= 2\n        k %= (1 << n)\n    if m_left:\n        qc.x(0)\n        qc.append(XGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n    if k_left & 1:\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [1])\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "ABC141F00433E", "submission_order": 4, "result": "WA", "execution_time": "1533 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom math import pi, acos, sqrt, asin\nfrom qiskit.circuit.library import XGate, ZGate, HGate, PhaseGate, RZGate, SwapGate\n\n# X を通すと回転量が -1 倍\n# X がかかっているかどうかを取得しないといけないのか\n# m = 0 なら， R^{k} -> R^{k + kr} or R^{k - kr}\n# m = 1 なら， R^{-k} -> R^{-k - kr} or R^{-k + kr}\n# mr = 0, m = 0 のとき， -k |00> + k |11>  -->  (-k - kr) |00> + (k + kr) |11>\n# mr = 0, m = 1 のとき， -k |10> + k |01>  -->  (k - kr) |10> + (-k + kr) |01>\n# 0 bit 目に R を適用，swap(0, 1)\n\n# mr = 1, m = 0 のとき， -k |00> + k |11>  -->  (-k - kr) |10> + (k + kr) |01>\n# mr = 1, m = 1 のとき，  k |01> - k |10>  -->  (k - kr) |00> + (-k + kr) |11>\n# 0 bit 目に R を適用，swap(0, 1) をして，x(0)\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n    # qc.x(0)\n    # qc.x(1)\n    qc.x(2)\n    # qc.x(3)\n    # Write your code here:\n    N = n - 1\n    k = k_left\n    for i in range(N):\n        qc.append(RZGate(2 * pi / (1 << N) * k).control(1), [i + 2, 0])\n        k *= 2\n        k %= (1 << n)\n    qc.swap(0, 1)\n    qc.append(SwapGate().control(N, ctrl_state='0' * N), list(range(2, N + 2)) + [0, 1])\n    if m_left:\n        qc.x(0)\n        qc.append(XGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [0])\n    if k_left & 1:\n        qc.append(ZGate().control(N, ctrl_state='0' * N), list(range(2, 2 + N)) + [1])\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AD543851F0726", "submission_order": 1, "result": "RE", "execution_time": "1628 ms", "memory": "140 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, RZGate\n\ndef A3(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m[0])\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n\ndef solve(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c = QuantumRegister(1), QuantumRegister(1), QuantumRegister(n - 1)\n    qc = QuantumCircuit(a, b, c)\n    # Write your code here:\n    qc.x(c)\n    if m_left:\n        qc.compose(ZGate().control(len(c)), [*c, a[0]], inplace=True)\n    if k_left % 2:\n        qc.compose(ZGate().control(len(c)), [*c, b[0]], inplace=True)\n    qc.x(c)\n    if m_right:\n        qc.compose(A3(n - 1), [b[0], *c], inplace=True)\n    for i in range(n - 1):\n        qc.compose(RZGate(2 ** (2 - n + i) * k_left * math.pi).control(1), [c[i], b[0]], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AD543851F0726", "submission_order": 2, "result": "RE", "execution_time": "1497 ms", "memory": "140 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, RZGate\n\ndef A3(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m[0])\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c = QuantumRegister(1), QuantumRegister(1), QuantumRegister(n - 1)\n    qc = QuantumCircuit(a, b, c)\n    # Write your code here:\n    qc.x(c)\n    if m_left:\n        qc.compose(ZGate().control(len(c)), [*c, a[0]], inplace=True)\n    if k_left % 2:\n        qc.compose(ZGate().control(len(c)), [*c, b[0]], inplace=True)\n    qc.x(c)\n    if m_right:\n        qc.compose(A3(n - 1), [b[0], *c], inplace=True)\n    for i in range(n - 1):\n        qc.compose(RZGate(2 ** (2 - n + i) * k_right * math.pi).control(1), [c[i], b[0]], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AD543851F0726", "submission_order": 3, "result": "RE", "execution_time": "1602 ms", "memory": "140 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, RZGate\n\ndef A3(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m[0])\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c = QuantumRegister(1), QuantumRegister(1), QuantumRegister(n - 1)\n    qc = QuantumCircuit(a, b, c)\n    # Write your code here:\n    qc.x(c)\n    if m_left:\n        qc.compose(ZGate().control(len(c)), [*c, a[0]], inplace=True)\n    if k_left % 2:\n        qc.compose(ZGate().control(len(c)), [*c, b[0]], inplace=True)\n    qc.x(c)\n    if m_right:\n        qc.compose(A3(n - 1), [b[0], *c], inplace=True)\n    for i in range(n - 1):\n        qc.compose(RZGate(2 ** (2 - n + i) * k_right * math.pi).control(1), [c[i], b[0]], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AD543851F0726", "submission_order": 4, "result": "AC", "execution_time": "1826 ms", "memory": "145 MiB", "code": "'''python\nimport math\n \nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library import XGate, ZGate, RZGate\n\ndef A3(n: int) -> QuantumCircuit:\n    m, k = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(m, k)\n    # Write your code here:\n    qc.x(m[0])\n    qc.x(k)\n    qc.compose(XGate().control(len(k)),[*k, m[0]], inplace=True)\n    qc.x(k)\n    return qc\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c = QuantumRegister(1), QuantumRegister(1), QuantumRegister(n - 1)\n    qc = QuantumCircuit(a, b, c)\n    # Write your code here:\n    qc.x(c)\n    if m_right:\n        qc.compose(ZGate().control(len(c)), [*c, a[0]], inplace=True)\n    if k_right % 2:\n        qc.compose(ZGate().control(len(c)), [*c, b[0]], inplace=True)\n    qc.x(c)\n    if m_right:\n        qc.compose(A3(n - 1), [b[0], *c], inplace=True)\n    for i in range(n - 1):\n        qc.compose(RZGate(2 ** (2 - n + i) * k_right * math.pi).control(1), [c[i], b[0]], inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AE4F1FBF1902F", "submission_order": 1, "result": "WA", "execution_time": "1901 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\nfrom qiskit.circuit.library.standard_gates import ZGate, XGate, XXPlusYYGate, RZZGate\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    qc.x(c)\n    qc.x(anc)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    if m_right == 0:\n        for i in range(n - 1):\n            qc.crz(zangle * k_right * (2**i), c[i], a)\n\n    else:\n        qc.cx(anc, a)\n\n        for i in range(n - 1):\n            qc.crz(zangle * k_right * (2**i), c[i], a)\n\n    qc.x(anc)\n\n    qc.h([*a, *b])\n    if m_right:\n        qc.cx(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cx(anc, b)\n\n    qc.h([*a, *b])\n\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AE4F1FBF1902F", "submission_order": 2, "result": "WA", "execution_time": "1688 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    for i in range(n - 1):\n        qc.crz(zangle * k_right * (2**i), c[i], b)\n\n    if m_right == 1:\n        qc.cx(anc, b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AE4F1FBF1902F", "submission_order": 3, "result": "WA", "execution_time": "1691 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    if m_right == 1:\n        qc.cx(anc, b)\n\n    for i in range(n - 1):\n        qc.crz(-zangle * k_right * (2**i), c[i], b)\n\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AE4F1FBF1902F", "submission_order": 4, "result": "WA", "execution_time": "1977 ms", "memory": "142 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    if m_right == 1:\n        qc.cx(anc, b)\n\n    sign = -1 if m_right == 0 else 1\n    for i in range(n - 1):\n        qc.crz(sign * zangle * k_right * (2**i), c[i], b)\n\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AE4F1FBF1902F", "submission_order": 5, "result": "WA", "execution_time": "2107 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    if m_right == 1:\n        qc.cx(anc, b)\n\n    sign = 1 if m_right == 0 else -1\n    for i in range(n - 1):\n        qc.crz(sign * zangle * k_right * (2**i), c[i], b)\n\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AE4F1FBF1902F", "submission_order": 6, "result": "WA", "execution_time": "1665 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n\n    sign = -1 if m_right == 0 else 1\n    for i in range(n - 1):\n        qc.crz(sign * zangle * k_right * (2**i), c[i], b)\n\n    if m_right == 1:\n        qc.cx(anc, b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AE4F1FBF1902F", "submission_order": 7, "result": "WA", "execution_time": "1620 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n\n    if m_right == 1:\n        qc.cx(anc, b)\n\n    for i in range(n - 1):\n        qc.crz(-zangle * k_right * (2**i), c[i], b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_B3", "user": "AE4F1FBF1902F", "submission_order": 8, "result": "AC", "execution_time": "1794 ms", "memory": "145 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nimport numpy as np\n\n\ndef solve(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n\n    if m_right == 1:\n        qc.cx(anc, b)\n\n    for i in range(n - 1):\n        qc.crz(zangle * k_right * (2**i), c[i], b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n'''"}
{"problem": "QPC005_EX", "user": "ACCDBBE2E33B6", "submission_order": 1, "result": "RE", "execution_time": "1569 ms", "memory": "141 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\nimport numpy as np\n\n\ndef b2(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_left:\n        qc.cz(anc, a)\n\n    if k_left % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    for i in range(n - 1):\n        qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    if m_left == 1:\n        qc.cx(anc, a)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef b3(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n\n    if m_right == 1:\n        qc.cx(anc, b)\n\n    for i in range(n - 1):\n        qc.crz(zangle * k_right * (2**i), c[i], b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef shift(n):\n    qc = QuantumCircuit(n)\n\n    for i in range(1, n):\n        qc.swap(0, i)\n\n    return qc\n\n\ndef cneg(n):\n    control, x = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(control, x)\n    qc.cx(control, x)\n\n    for idx in reversed(range(n)):\n        qc.mcx([control] + x[:idx], x[idx])\n\n    return qc\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * np.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef mk_to_emk(n):\n    m, k, anc = QuantumRegister(1), QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(m, k, anc)\n\n    qc.compose(qft(n), k, inplace=True)\n    qc.compose(shift(n), k, inplace=True)\n    qc.compose(cneg(n), k, inplace=True)\n\n    qc.x(k[1:])\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    # c=0\n    qc.ch(anc, m)\n\n    qc.x(k[1:])\n    # c>0\n    qc.cx([*anc, k[0]], m)\n\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    return qc\n\n\ndef solve(\n    n: int, m_before: int, k_before: int, m_after: int, k_after: int\n) -> QuantumCircuit:\n    qc = QuantumCircuit(n + 1)\n\n    qc.compose(mk_to_emk(n), inplace=True)\n    qc.compose(b3(n, m_before, k_before), inplace=True)\n    qc.compose(b2(n, m_after, k_after), inplace=True)\n    qc.compose(mk_to_emk(n).inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_EX", "user": "ACCDBBE2E33B6", "submission_order": 2, "result": "WA", "execution_time": "1914 ms", "memory": "143 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\nimport numpy as np\n\n\ndef b2(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_left:\n        qc.cz(anc, a)\n\n    if k_left % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    for i in range(n - 1):\n        qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    if m_left:\n        qc.cx(anc, a)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef b3(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n\n    if m_right:\n        qc.cx(anc, b)\n\n    for i in range(n - 1):\n        qc.crz(zangle * k_right * (2**i), c[i], b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef shift(n):\n    qc = QuantumCircuit(n)\n\n    for i in range(1, n):\n        qc.swap(0, i)\n\n    return qc\n\n\ndef cneg(n):\n    control, x = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(control, x)\n    qc.cx(control, x)\n\n    for idx in reversed(range(n)):\n        qc.mcx([control] + x[:idx], x[idx])\n\n    return qc\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * np.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef mk_to_emk(n):\n    m, k, anc = QuantumRegister(1), QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(m, k, anc)\n\n    qc.compose(qft(n), k, inplace=True)\n    qc.compose(shift(n), k, inplace=True)\n    qc.compose(cneg(n - 1), k, inplace=True)\n\n    qc.x(k[1:])\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    # c=0\n    qc.ch(anc, m)\n\n    qc.x(anc)\n    # c>0\n    qc.mcx([*anc, k[0]], m)\n\n    qc.x(k[1:])\n    qc.x(anc)\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    return qc\n\n\ndef solve(\n    n: int, m_before: int, k_before: int, m_after: int, k_after: int\n) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n    qc = QuantumCircuit(a, b, c, anc)\n\n    qc.compose(mk_to_emk(n), inplace=True)\n    qc.compose(b3(n, m_before, k_before), inplace=True)\n    qc.compose(b2(n, m_after, k_after), inplace=True)\n    qc.compose(mk_to_emk(n).inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_EX", "user": "ACCDBBE2E33B6", "submission_order": 3, "result": "RE", "execution_time": "1948 ms", "memory": "140 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\nimport numpy as np\n\n\ndef b2(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_left:\n        qc.cz(anc, a)\n\n    if k_left % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    for i in range(n - 1):\n        qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    if m_left:\n        qc.cx(anc, a)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef b3(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n\n    if m_right:\n        qc.cx(anc, b)\n\n    for i in range(n - 1):\n        qc.crz(zangle * k_right * (2**i), c[i], b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef shift(n):\n    qc = QuantumCircuit(n)\n\n    for i in range(1, n):\n        qc.swap(0, i)\n\n    return qc\n\n\ndef cneg(n):\n    control, x = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(control, x)\n    qc.cx(control, x)\n\n    for idx in reversed(range(n)):\n        qc.mcx([control] + x[:idx], x[idx])\n\n    return qc\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * np.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef mk_to_emk(n):\n    m, k, anc = QuantumRegister(1), QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(m, k, anc)\n\n    qc.compose(qft(n), k, inplace=True)\n    qc.compose(shift(n), k, inplace=True)\n    qc.compose(cneg(n - 1), k, inplace=True)\n    qc.x(k[0])\n\n    qc.x(k[1:])\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    # c=0\n    qc.ch(anc, m)\n\n    qc.x(anc)\n    # c>0\n    qc.mcx([*anc, k[0]], m)\n\n    qc.x(k[1:])\n    qc.x(anc)\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    return qc\n'''"}
{"problem": "QPC005_EX", "user": "ACCDBBE2E33B6", "submission_order": 4, "result": "WA", "execution_time": "2236 ms", "memory": "146 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\nimport numpy as np\n\n\ndef b2(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_left:\n        qc.cz(anc, a)\n\n    if k_left % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    for i in range(n - 1):\n        qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    if m_left:\n        qc.cx(anc, a)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef b3(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n\n    if m_right:\n        qc.cx(anc, b)\n\n    for i in range(n - 1):\n        qc.crz(zangle * k_right * (2**i), c[i], b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef shift(n):\n    qc = QuantumCircuit(n)\n\n    for i in range(1, n):\n        qc.swap(0, i)\n\n    return qc\n\n\ndef cneg(n):\n    control, x = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(control, x)\n    qc.cx(control, x)\n\n    for idx in reversed(range(n)):\n        qc.mcx([control] + x[:idx], x[idx])\n\n    return qc\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * np.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef mk_to_emk(n):\n    m, k, anc = QuantumRegister(1), QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(m, k, anc)\n\n    qc.compose(qft(n), k, inplace=True)\n    qc.compose(shift(n), k, inplace=True)\n    qc.compose(cneg(n - 1), k, inplace=True)\n    qc.x(k[0])\n\n    qc.x(k[1:])\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    # c=0\n    qc.ch(anc, m)\n\n    qc.x(anc)\n    # c>0\n    qc.mcx([*anc, k[0]], m)\n\n    qc.x(k[1:])\n    qc.x(anc)\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    return qc\n\n\ndef solve(\n    n: int, m_before: int, k_before: int, m_after: int, k_after: int\n) -> QuantumCircuit:\n    m, k, anc = (\n        QuantumRegister(1),\n        QuantumRegister(n),\n        QuantumRegister(1),\n    )\n    qc = QuantumCircuit(m, k, anc)\n\n    qc.compose(mk_to_emk(n), inplace=True)\n    qc.compose(b3(n, m_before, k_before), inplace=True)\n    qc.compose(b2(n, m_after, k_after), inplace=True)\n    qc.compose(mk_to_emk(n).inverse(), inplace=True)\n\n    return qc\n'''"}
{"problem": "QPC005_EX", "user": "ACCDBBE2E33B6", "submission_order": 5, "result": "AC", "execution_time": "1878 ms", "memory": "147 MiB", "code": "'''python\nfrom qiskit import QuantumCircuit, QuantumRegister\nfrom qiskit.circuit.library.standard_gates import HGate\nimport numpy as np\n\n\ndef b2(n: int, m_left: int, k_left: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_left:\n        qc.cz(anc, a)\n\n    if k_left % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n    for i in range(n - 1):\n        qc.crz(zangle * k_left * (2**i), c[i], a)\n\n    if m_left:\n        qc.cx(anc, a)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef b3(n: int, m_right: int, k_right: int) -> QuantumCircuit:\n    a, b, c, anc = (\n        QuantumRegister(1),\n        QuantumRegister(1),\n        QuantumRegister(n - 1),\n        QuantumRegister(1),\n    )\n\n    qc = QuantumCircuit(a, b, c, anc)\n    zangle = 2 * np.pi / (2 ** (n - 1))\n\n    # Ancilla (|anc> = |c=0>)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    # c = 0\n    if m_right:\n        qc.cz(anc, a)\n\n    if k_right % 2 == 1:\n        qc.cz(anc, b)\n\n    # c != 0\n    qc.x(anc)\n\n    if m_right:\n        qc.cx(anc, b)\n\n    for i in range(n - 1):\n        qc.crz(zangle * k_right * (2**i), c[i], b)\n\n    # Uncompute\n    qc.x(anc)\n    qc.x(c)\n    qc.mcx(c, anc)\n    qc.x(c)\n\n    return qc\n\n\ndef shift(n):\n    qc = QuantumCircuit(n)\n\n    for i in range(1, n):\n        qc.swap(0, i)\n\n    return qc\n\n\ndef cneg(n):\n    control, x = QuantumRegister(1), QuantumRegister(n)\n    qc = QuantumCircuit(control, x)\n    qc.cx(control, x)\n\n    for idx in reversed(range(n)):\n        qc.mcx([control] + x[:idx], x[idx])\n\n    return qc\n\n\ndef qft(n):\n    qc = QuantumCircuit(n)\n\n    thetas = []\n    for k in range(0, 1 + n):\n        thetas.append(2 * np.pi / (2**k))\n\n    for idx in range(0, n):\n        qc.h(n - 1 - idx)\n        for jdx in range(idx + 1, n):\n            thetaidx = jdx - idx + 1\n            qc.cp(thetas[thetaidx], n - 1 - jdx, n - 1 - idx)\n\n    for idx in range(0, n // 2):\n        qc.swap(idx, n - idx - 1)\n\n    return qc\n\n\ndef mk_to_emk(n):\n    m, k, anc = QuantumRegister(1), QuantumRegister(n), QuantumRegister(1)\n    qc = QuantumCircuit(m, k, anc)\n\n    qc.compose(qft(n), k, inplace=True)\n    qc.compose(shift(n), k, inplace=True)\n    qc.compose(cneg(n - 1), k, inplace=True)\n\n    qc.x(k[1:])\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    # c=0\n    qc.ch(anc, m)\n\n    qc.x(anc)\n    # c>0\n    qc.cx(anc, k[0])\n    qc.mcx([*anc, k[0]], m)\n\n    qc.x(k[1:])\n    qc.x(anc)\n    qc.mcx(k[1:], anc)\n    qc.x(k[1:])\n\n    return qc\n\n\ndef solve(\n    n: int, m_before: int, k_before: int, m_after: int, k_after: int\n) -> QuantumCircuit:\n    m, k, anc = (\n        QuantumRegister(1),\n        QuantumRegister(n),\n        QuantumRegister(1),\n    )\n    qc = QuantumCircuit(m, k, anc)\n\n    qc.compose(mk_to_emk(n), inplace=True)\n    qc.compose(b3(n, m_before, k_before), inplace=True)\n    qc.compose(b2(n, m_after, k_after), inplace=True)\n    qc.compose(mk_to_emk(n).inverse(), inplace=True)\n\n    return qc\n'''"}